Core Information

Course CEE 482/582 Introduction to Coastal Engineering Lecture 3 hours; 3 credits Spring Semester, ODU Campus Session Spring Session #1 Instructor Dr. David R. Basco, Professor, P.E., Ph.D. CEE, KH Rm. 136 Phone (757) 683-3223 Fax (757) 683-5354 e-mail <basco@cee.odu.edu>

Course Description

HOW TO: Use linear theory, wave characteristic formulas Use wave tables (Weigel, 1966), formulas, software Calculate wave properties (pressure, velocity, acceleration) Use Rayleigh distribution for statistical waves Calculate wave energy density spectrum Make wave hindcast/forecast(s) Relate energy density spectrum to "significant" wave height Draw/Construct wave refraction diagram by hand Determine tidal variations and storm surge statistics at your site Understand wave transformations at coastal sites (shoaling, refraction, breaking, reflection) Calculate the longshore sediment transport rate Conduct an engineering sediment budget study Relate beach volume change to shoreline change (erosion/accretion) Conduct a beach sand gradation analysis (VAT) Estimate size of armor stone for breakwaters Understand how coastal zone management operates at your site (city, county, state, country) Estimate shoreline change using a one-line model Study further (references, journals, conference proceedings, reports, etc.) FUTURE COURSES TO COVER: Dredging and Beach Engineering, CEE 687 Design of Coastal Structures, CEE 782/882 Coastal Hydrodynamics and Sediment Transport, CEE 788/888 Computational Environmental Fluid Dynamics, CEE 789/889

Textbook and References

Required Textbook: See Textbook information References: None

Tentative Course Outline

CEE 482/582 Introduction to Coastal Engineering Lecture 3 hours; 3 credits ODU Campus, Teletechnet sites, Internet (visual streaming) Spring Session Today is Week Topics Chapter Pages 1 Introduction, What is Coastal Engineering? 1 1-20 Introduction to water waves 2 21-30 2 Derivation of linear wave theory 2 31-35 Calculation of wave length, L, methods 2 36 3 Calculation of pressure, velocity, acceleration. 2 36-41 Calculation of energy, group celerity, tables 7 149-150 4 Short term wave analysis, irregular waves 3 51-53 The Rayleigh distribution 3 54-58 5 Long-term wave analysis 4 81-89 Wave generation - winds 5 103-106 6 Simple wave hindcasting, models 5 107-116 Review for Mid-Term Exam 1-5   7 Mid-Term Examination 1-5   8 Tides 6 117-133 Water levels 6 134-144   Spring Break     9 Wave transformations, refraction 7 149-158 Wave breaking 7 159-160 10 Rubble-mound stability, Hudson formula 9 210-214 Basic shore processes 12 281-283 11 The beach, materials, profiles 12 283-288 Longshore sediment transport rate 12 288-297 12 Theory - One Line Model planform change 14 331- Numerical solutions, models 14 -352 13 Shore protection alternatives 15 363- Artificial beach nourishment 15 -380 14 Introduction to Coastal Management 10 All Review for Final Exam 6-15     Final Examination