CIV E 632-COMPUTATIONAL HYDRAULICS AND HYDROLOGY SPRING 2010 INSTRUCTOR:  DR. V. M. PONCE TEXT:  Online syllabus

No.          Description          [Paper No.]          (Week) Shallow-wave propagation     [1, 2, 3, 4, 5]   (1,2) Muskingum-Cunge method     [6, 7, 8, 9, 10]   (3) Kinematic waves     [11, 12, 13, 14]   (4) Diffusion waves     [15, 16, 17, 18, 19, 20]   (5,6) Dynamic waves     [21, 22]   (7) Roll waves     [23, 24, 25]   (9) Numerical modeling     [26, 27, 28, 29]   (10-11) Applications:    (12-15) Watershed routing    [30, 31] Sediment routing    [32, 33] Dam-breach modeling    [34] Water quality    [35] Two-dimensional modeling     [36] Groundwater modeling     [37]

PAPERS Shallow wave propagation in open-channel flow   (3103)   (4108) Applicability of kinematic and diffusion models  (3104) On kinematic waves: Flood movement in long rivers  (4501) On the subject of a flood propagation computation method  (4502) Mathematical simulation of surface flow  (4503) Muskingum-Cunge method with variable parameters  (3309)  (3106) Accuracy criteria in diffusion routing  (3117) Analytical verification of Muskingum-Cunge routing  (3146) Simplified Muskingum routing equation  (3108) Variable-parameter Muskingum-Cunge method revisited  (3309)  (3139) Nature of wave attenuation in open-channel flow  (3116) The kinematic wave controversy  (3130) Kinematic wave modeling: Where do we go from here?  (3132) Kinematic shock: Sensitivity analysis  (3120) Diffusion wave modeling of catchment dynamics  (3122) New perspective on the Vedernikov number  (3131) New perspective on the convection-diffusion-dispersion equation  (3138) Generalized diffusion wave equation with inertial effects   (3309)   (3129) Dam-breach flood wave propagation using dimensionless parameters  (3163)  (7905) Linear reservoirs and numerical diffusion   (3308)   (3113) Modeling looped ratings in Muskingum-Cunge routing   (3309)   (3160) Time of opening of irrigation canal gates  (3153) The criterion for the possibility of roll-wave formation  (4506) Verification of theory of roll-wave formation  (3133) Effect of cross-sectional shape on free-surface instability  (3137) A study of the numerical solution of partial differential equations  (4504) Unconditional stability in convection computations  (3111) Convergence of four-point implicit water wave models  (3105) The convergence of implicit bed transient models  (3110) Parking-lot storage modeling using diffusion waves  (3154) Large basin deterministic hydrology: A case study  (3121) Celerity of transient bed profiles  (3118) Modeling alluvial channel bed transients  (3109) Modeling gradual dam breaches  (3114) Differential equation for DO sag curve  (4339) Modeling circulation in depth-averaged flow  (3115) A convergent explicit groundwater model  (3501)

CALENDAR Week No. 6:   Topic selection deadline (Monday, March 1, 1900) Week No. 7:   Midterm exam (Monday, March 8, 1730-1845) Week No. 10:   Preliminary oral presentations (Wednesday, April 7, 1730-1845) Week No. 15:   Final oral presentations (Wednesday, May 12, 1730-1845) Week No. 15:   Papers due (Wednesday, May 12, 1730) Week No. 16:   Final exam (Thursday, May 13, 1030-1230).

INSTRUCTIONS OFFICE HOURS: MW 1100-1200; MW 2015-2115 (PS231-B). GRADING POLICY:   Homework Set (25%), Midterm (25%), Project (25%), Final (25%). HOMEWORK SET:   Homework is due at the start of the class period, one week after date of assignment. There is no late homework. PROJECT:   The project will consist of individual work on a topic mutually agreed with the instructor. A written paper and two oral presentations [preliminary (30% progress) and final] (10th and 15th week, respectively) are an integral part of the experience. The paper should be of professional quality and its length should not be more than 15 pages, including tables and figures. Text should be double-spaced. The oral presentations should be Power Point.