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Home My WebLink About3821; Calavera Lake Creek & Agua Hedionda Creek; Hydrological Study Calavera Lake & Aqua Hedionda; 1989-07-01H YDROL.OG I OAL STUDY FOR NORTHEASTERN CARLSBAD BASINS OF CALAVERA LAKE CREEK AND AQUA HEDIONDA CREEK prepared by Howard H. Chang Ph.D., P.E. July 1989 TABLE OF CONTENTS page I. INTRODUCTION 1 II. DRAINAGE BASIN CHARACTERISTICS 2 III. STORAGE ROUTING THROUGH CALAVERA LAKE 5 IV. RESULTS OF HYDROLOGY STUDY 7 V. FLOOD PLAIN STUDY FOR MOBILE HOME PARK 10 VI. RECOMMENDATIONS FOR DRAINAGE IMPROVEMENT 11 REFERENCES 12 FIGURES APPENDIX A: INPUT/OUTPUT LISTINGS OF HYDROLOGY STUDY (HEC-1) APPENDIX B. INPUT/OUTPUT LISTINGS OF HEC-2 STUDY FOR MOBILE HOME PARK ATTACHMENTS Drainage Map of Calavera Lake Creek and Aqua Hedionda Creek Flood Plain Map at Mobile Hone Park HYDROLOGICAL STUDY FOR NORTHEASTERN CARLSBADm BASINS OF CALAVERA LAKE CREEK " AND AQUA HEDIONDA CREEK m I. INTRODUCTION m This hydrology study was made for the northeastern quadrant of the City of «, Carlsbad, covering Zones 7, 14, and 15. The area is drained by two major m streams: Aqua Hedionda Creek and Calavera Lake Creek, as shown in the attached maps. The purpose of the study is to obtain the 100-year flood discharges of streams within the designated zones. Reconmendations will also be made to solve*• the inadequate drainage situation of Calavera Lake Creek through the Rancho Carlsbad Mobile Home Park. A unified approach in hydrology is applied to all streams in these zones. The hydrology study considers the ultimate development """ under the established development constraints, so that the results are also valid "•* in the long term. M, This study is guided by the Hydrology Manual of the County of San Diego, updated in 1985. As specified in the manual, the SCS method for hydrology shall be applied to drainage basins that are larger than 0.5 square mile. The HEC-1 computer model developed by the U. S. Army Corps of Engineers, which employs the•<«SCS method, is the principle tool for this study. The drainage basins as JW selected in this study are also parts of larger basins which extend outside the """ city limit. For each case, the entire drainage basin is included in the m computation, as shown in the drainage basin map. •mi • The Hydrology Manual also specifies the use of the rational method for ^ drainage basins that are less than 0.5 square mile in area. The rational method is a simpler method which provides the design discharge of specific drain facilities. This study does not cover the rational method since such facilities are selected with future development. An impotent objective of the present study is to develop an adequate means of drainage for the mobile home park. The existing shallow channel through the park is silted and inadequate to convey the 100-year flood. A suitable configuration of the channel, subject to given physical constraints, shall be determined. Reduction of the flood discharge, if necessary, using flood water detention basins or operation method of Calavera Lake are among the alternatives to be investigated. The flood level and flood plain boundary of Aqua Hedionda Creek through the Rancho Carlsbad Mobile Home Park is computed using the HEC-2 program for the discharges determined in this hydrology study. However, channel improvement, if needed, is not investigated in this study. II. DRAINAGE BASIN CHARACTERISTICS Drainage basins are delineated for the northeastern area of the City within Zones 7, 14, and 15. Points of concentration along the principal drainage courses are also delineated on the drainage map. For the purpose of hydrological computation, certain basin characteristics are required. Such characteristics include basin area, precipitation zone number (PZN), antecedent moisture condition, precipitation, SCS curve number (CN), lag time, etc. Methods for obtaining such characteristics are described below separately. Basin Area - The area of a drainage basin is measured directly from the drainage basin map. Work maps used for this purpose have scales equal to or greater than 1" = 400'. Precipitation Zone Number (PZN) - This value for a basin is obtained from Fig. I-A-3 of the County Hydrology Manual. The coastal line has the PZN value of 1 and the PZN of 1.5 line cuts through the eastern edge of the study area. Basins in the study area have PZN values ranging from 1.2 to 1.6. Antecedent Moisture Condition (AMC) - The AMC for the 100-year flood is computed based on the PZN value of the basin according to the following relation /PZN - 1.0AM: = 2.0 + (3.o - 2.o)( --------- \2.0 -1.0 Runoff Curve Number (CN) - In the SCS method for runoff estimation, the CN value is used. Table I-A-1 of the Hydrology Manual lists the CN values related to land use, land treatment or practice, hydrologic condition, and soil type. The CN values for the AMC of 2 are listed in the manual. Adjustment to other AMCs is based on the information shown in Table I-A-5 of the manual. Precipitation - The 100-year 6-hour storm and 24-hour storm are used in this study. The precipitation in inches for each case is obtained from the precipitation map in the Hydrology Manual. The values so obtained are listed in Tables 1 and 2. precipitation is distributed in accordance with the Type B distribution curve. When both storms are applied in the study, the 6-hour storm normally produces higher runoff discharges in small basins, while the 24-hour storm generates higher discharges for large basins. The larger of the two discharges so obtained is adopted. Lag Time - The lag time relationship is based on criteria developed by the U. S. Army Crops of Engineers adopted in the Hydrology Manual. Lag is defined as the time in hours from the center of mass of the excess rainfall to the peak discharge, it is an empirical expression of the physical characteristics of a drainage area in terms of time, and is estimated as: Lag (hours) = 24 n 'L * Lc\ m where n = Basin factor, representing a measure of overall basin roughness; m = 0.38, a constant; L = Length of the longest water course in miles; Lc = Length along longest course in miles, measured upstream to the point opposite the center of area; S = Overall slope, in feet per mile, of the longest water course. Table 1. Sunmary of Drainage Basin Characteristics for Calavera Lake Creek Basin Basin Al A2 A3 A4 A5 A6 A7 A8 A9 A10 All A12 LI L2 L3 Total Area sq. mi. 0.74 0.21 0.48 0.68 0.20 0.50 0.20 0.29 0.31 0.36 0.23 0.34 0.49 0.48 0.39 area =5.90 Table PZN 1.5 1.4 1.35 1.4 1.3 1.3 1.25 1.3 1.25 1.2 1.25 1.2 1.3 1.3 1.25 square ATC 2.5 2.4 2.35 2.4 2.3 2.3 2.25 2.3 2.25 2.2 2.25 2.2 2.3 2.3 2.25 miles 100-Yr. 6-hr 2.9 2.9 2.85 2.9 2.8 2.8 2.8 2.8 2.75 2.7 2.75 2.7 2.8 2.8 2.75 Rainfall, in. 24-hr. 5.1 5.1 5.0 5.1 4.9 4.9 4.9 4.9 4.75 4.5 4.75 4.5 4.9 4.9 4.75 CN 90 90 89 90 87 87 88 88 90 87 86 87 86 86 86 Lag Time hours 0.45 0.23 0.25 0.49 0.19 0.25 0.21 0.26 0.18 0.19 0.21 0.23 0.35 0.27 0.30 2. Summary of Drainage Basin Characteristics for Aqua Basin UA UB UC UD UE UF UG H Area sq. mi. 6.50 3.00 1.65 0.42 0.24 1.11 1.15 0.28 PZN 1.6 1.6 1.4 1.35 1.35 1.4 1.35 1.3 Ate 2.6 2.6 2.4 2.35 2.35 2.4 2.35 2.3 Hedionda Creek Basin 100-Yr. Rainfall, in. 6-hr 3.2 3.15 3.0 2.85 2.85 2.95 2.85 2.8 24-hr. 5.5 5.4 5.25 5.0 5.0 5.2 5.0 4.9 CN 91 91 89 89 88 89 89 88 Lag Time hours 1.02 0.76 0.60 0.22 0.17 0.46 0.41 0.26 G F E D C B A13 A14 A 0.51 0.96 0.58 0.34 0.30 0.25 0.17 0.43 0.28 1.3 1.3 1.25 1.25 1.25 1.2 1.2 1.2 1.2 2.3 2.3 2.25 2.25 2.25 2.2 2.2 2.2 2.2 2.8 2.8 2.75 2.75 2.75 2.7 2.7 2.7 2.7 4.9 4.9 4.75 4.75 4.75 4.5 4.5 4.5 4.5 87 91 86 86 90 87 87 87 86 0.38 0.17 0.23 0.16 0.12 0.24 0.24 0.18 0.10 Total area of two stream basins = 24.09 square miles III. STORAGE ROUTING THROUGH CALAVERA LAKE Calavera Lake is an important factor to stream discharge since the lake contributes to the attenuation of the peak discharge due to the storage of flood water provided by its volume. As-built plans of the dam and spillway are given in Fig. 1, provided by the Carlsbad Municipal Water District. The spillway consists of a broad-crested weir with a length of 150 feet and a crest elevation of 216.5 feet. A 7'-diameter standing pipe is located in the lake near the dam. Information concerning drainage devices on the standing pipe was obtained from Mr. Bryan Troupe of the Water District (Telephone number 438-2722). Only manual devices existed before; but about five years ago, permanent drain was installed to comply with the regulations of the California Department of Dam Safety. The permanent drain device consists of a 12-inch pipe, which is a 90 degree elbow pointing downward as shown in the figure. The drain opening is at the elevation of 208.92, or 7.58 feet below the spillway crest. The downward inlet of the drain pipe is intended to avoid blockage by floating debris. Iron bars are installed at the pipe entrance to prevent large objects from entering the pipe. The elbow pipe also has many l"-diameter holes around the surface as additional drain inlets. The permanent drain maintains the lake at a level no higher than 208.92 feet during the normal period. According to Mr. Troupe, the lake level is usually lowered a couple of feet below the elevation of 208.92 before a storm. This lowering of lake level is through a manually-controlled drainage pipe. They have not yet observed blockage of the permanent drainage pipe since its installation. Access to the standing pipe is provided by a boat. Because of the permanent drain pipe, the normal lake level should be no higher than 208.92 feet, in the hydrology study, the initial lake level for the 100-year storm is assumed to be at the drain level. Storage routing of flood flow through the reservoir is based on the continuity equation for water, ie. Inflow - Outflow = Rate of lake storage This option is included in the HEC-1 program as the modified Puls routing method. CXatflow from the lake is controlled at the spillway, for which the discharge is computed using the equation Q = C L H3/2 where H is the head of water above the spillway crest, L is the weir length, and C is the weir coefficient which is estimated to be 2.63 for the broad-crested weir. In the storage routing, the elevation-surface area relation for the lake is also employed. The tabulation for elevation-surface area of the lake is given below. Elevation Surface Area feet 208 210 212 214 216 217 218 219 220 221 acres 21 24 27 30 33 35 38 39.5 41 43 Results of the routing simulation for the 100-year 24-hour storm is shown in Fig. 2. It shows the inflow hydrograph and the routed outflow hydrograph. The peak discharge for the former is 1,803 cfs and that for the latter is 1,171 cfs. The attenuation of peak discharge is therefore 35% for the 24-hour storm. This attenuation is 80% for the 6 hr. storm. There are other routing studies of the lake. A comparison of routing study results are listed below. However, it should be noted that earlier routing studies were made before the installation of the permanent drain pipe. A more conservative assumption concerning the initial lake level should be employed; the full lake level was assumed in the earlier studies. Name of Study Discharge of Inflow Discharge of Outflow cfs cfs Shuirman-Simpson, 1973 2,134 1,893 County of San Diego 1976 2,300 900 This Study per 6-hr storm 2,347 477 per 24-hr storm 1,803 1,171 The discrepancy in results may also be attributed to the type of storm used, Such information for other studies could not be obtained to make a comparison. IV. RESULTS OF HYDROLOGY STUDY Results of the hydrology study are surrmarized in Table 3. Other detailed output information can be found from the computer listings of HEC-1 in Appendix A. For the 6-hr, and 24-hr, storms, only the higher of two discharges is listed. It can be seen that the 6-hr, storm produces higher discharges in smaller basins while the 24-hr, storm generates higher values for larger basins. This procedure was not followed by all previous studies. Table 3. Summary of peak Discharges for the 100-Year Flood Pt. of Con Drainage Area 6-hr Storm 24-hr storm -cent rat ion Location in square miles in cfs in cfs 1 Calavera Lake Creek at exit of Basins Al and A2 0.95 674 2 Calavera Lake Creek at Exit of Basins A3 and A4 2.11 1,445 3 Calavera Lake Creek at Exit of Basins A5 and A6 2.81 1,850 4 Calavera Lake Creek at eas- tern end of Calavera Lake 3.30 2,155 5 Calavera Lake Creek just upstream of Calavera Dam 3.61 2,347 1,803 5 Calavera Lake Creek just downstream of Calavera Dam 3.61 1,171 6 Calavera Lake Creek at exit of Basins A10 and All 4.20 1,236 7 Calavera Lake Creek at Exit of Basins LI and L2 0.97 614 8 East Branch of Calavera Lake Creek just before entrance of mobile home park 1.36 811 8 Calavera Lake Creek just before entrance of mobile home park 4.54 1,353 8 Calavera Lake Creek at entrance of mobile home park, combined flow from north and east 5.90 1,739 10 Aqua Hedionda Creek just downstream of confluence with Buena Creek at Green Oak Ranch 9.50 5,299 11 Aqua Hedionda Creek at exit of Basins UE, UF and UG near City limit 12.0 5,962 13 Aqua Hedionda Creek at exit of Basins UC and UD 2.07 1,231 14 Aqua Hedionda Creek at exit of Basin H 2.42 1,383 12 Aqua Hedionda Creek just downstream of confluence with unnamed tributary 15.89 7,597 15 Aqua Hedionda Creek at 300' upstream from Rancho Carlsbad 16.47 7,809 17 Aqua Hedionda Creek at 130' upstream from Rancho Carlsbad 17.05 7,997 18 Aqua Hedionda Creek just upstream of confluence with Calavera Lake Creek 17.30 8,080 18 Aqua Hedionda Creek just downstream of confluence with Calavera Lake Creek 23.80 9,848 19 Aqua Hedionda Creek just downstream of El Camino Real Bridge 24.09 9,910 The discharges obtained in this study are compared with those given in previous studies. The comparison is listed in Table 4. It is important to remember, again, that discharges obtained in this study are affected by the drain modification in Lake Calavera around 1985, and this condition did not exist when earlier studies were made, in the Rick study of 1983, the storage effect of Calavera Dam was not considered since the flood flow was not routed through the lake. Table 4. Comparison of Peak Discharges for 100-Year Flood Point Area This Study Rick County Corps Vista Cone. Location sq. mi. 1989 1983 1976 1973 1979 5 Calavera Lake Creek just upstream of Calavera Dam 3.61 2,347 2,300 5 Calavera Lake Creek just downstream of Calavera Dam 3.61 1,171 900 8 Calavera Lake Creek at entrance of mobile home park, combined flow from north and east 5.90 1,739 3,512 1,400 10 Aqua Hedionda Creek just downstream of confluence with Buena Creek at Green Oak Ranch 9.50 5,299 5,621 7,000 6,900 5,035 11 Aqua Hedionda Creek near Carlsbad City limit 12.00 5,962 7,200 12 Aqua Hedionda Creek just downstream of confluence with unnamed tributary 15.58 7,462 7,700 7,900 18 Aqua Hedionda Creek just upstream of confluence with Calavera Lake Creek 17.30 8,080 9,965 7,900 18 Aqua Hedionda Creek just downstream of confluence with Calavera Lake Creek 23.80 9,848 13,472 10,000 10,300 V. FLOOD PLAIN STUDY FOR MOBILE HOME PARK The scope of the flood plain study covers Aqua Hedionda Creek from the bridge at El Camino Real to the eastern boundary of Rancho Carlsbad Mobile Home Park (Rancho Carlsbad Drive). The purpose of the study is to determine the flood level and flood plain boundary of Aqua Hedionda Creek for the discharges obtained in this study. Cross-sectional profiles for Aqua Hedionda Creek are given in Figs. 3 to 20. The Calavera Lake Creek through the mobile home park has been silted in recent years. A solution for this drainage problem would include redredging of the creek channel and the par t of Aqua Hed i onda Creek from the Calavera confluence to El Camino Real Bridge. The extent of dredging in the 300-foot reach of Aqua Hedionda Creek has been determined to be 2.5 feet from the surveyed bed level as shown in Fig. 4. The restored Calavera Lake Creek in the mobile home park is assumed to be a trapezoidal channel with a bottom width of 7 feet and a side slope of 1.5 to 1. The channel-bed slope is 0.004 for the 2,000-foot lower reach from the confluence with Aqua Hedionda Creek; the slope is 0.0068 for the upper reach of about 1,250 feet. 10 The flood plain study is on the assumption that channel improvement items described herein are implemented. The computed water-surface profile Calavera Lake Creek is shown in Fig. 21. Flood plain studies for Aqua Hedionda Creek have been made by Rick Engineering, 1983; it covers the creek from the coastal lagoon through Rancho Carlsbad Mobile Home Park and Rancho Carlsbad Golf Course. Previous cross sections are used in this study but they are updated to reflect recent changes. Since the completion of the Rick Engineering study, the bridge at Rancho Carlsbad Drive has been modified. The new configuration is used in this study. The present bridge has triple box culverts. The width of each box is 12 feet and the height varies from about 12 feet to 10 feet, reflecting the uneven bed profile. This study has been made using the HEC-2 computer model developed by the U. S. Army Crops of Engineers. Ineffective flow areas in the flood plain are specified using the ET or x3 records. The input and output listings are submitted with the report (see Appendix B) , together with a map showing the cross section locations and flood plain boundary (see Attachment). The plotted results include the cross-section profiles, channel-bed profile, and water-surface profile. The Rancho Carlsbad Drive Bridge on Aqua Hedionda Creek is insufficient to pass the 100-year flood, with a portion of the flow overtopping the bridge roadway. The overtopped flow will spread to the mobile home park downstream to become perched flow for the flood plain. The boundary affected by the perched flow is not shown in the map. IV. RECOMMENDATIONS FOR DRAINAGE IMPROVEMENT On the basis of the study results, certain recommendations are made in order to improve the current drainage condition though the mobile home park. The current shallow channel of Calavera Lake Creek is insufficient to pass the design flood discharge of 1,740 cfs. 11 1. Restoration of the Calavera Lake Creek through the mobile home park by dredging. The design discharge of 1,740 cfs may be accommodated by a proper channel improvement within the physical constraint of 40-foot surface width. An adequate channel configuration is given in the previous section. The channel boundary needs to be protected against the peak velocity of about 10 feet per second. Protection of the channel boundary may be achieved by using such materials as armorflex or geoweb. 2. Dredging of the short channel reach, about 300 feet long, of Aqua Hedionda Creek from the Calavera Lake Creek confluence to El Camino Real Bridge by 2.5 feet. 3. Future siltation of the channel may be prevented by sediment detention basins installed upstream of the mobile home park. Two such facilities are recommended, with one on the north channel branch and one on the east branch. 4. The Rancho Carlsbad Bridge on Aqua Hedionda Creek is insufficient to pass the 100-year flood of about 8,000 cfs, with a portion the flow overtopping the bridge roadway. The overtopped flow will spread to the downstream to becone perched flow for the downstream flood plain. This situation may be improvement by enlargement of the bridge opening or by raising the bridge span. REFERENCES 1. "Calavera Dam inundation Study, City of Carlsbad", Shuirman-Simpson Consulting Engineers, September 1973. 2. "Flood Plain information, Aqua Hedionda Creek", Department of the Army, Los Angeles District, Corps of Engineers, July 1973. 3. "Aqua Hedionda Creek", County of San Diego, 1976. 4. "Drainage Master Plan, City of Vista", L & S Consultants, San Marcos, CA, 1978. 5. "Rancho Carlsbad Drainage and Flood Plain Study", Rick Engineering Company, June, 1983. 6. "Hydrology Manual", County of San Diego, January 1985. 12 lllllllllililililllllllilllilll I t I I I Fig. 1. Calavera Dam and Spillway (on second sheet) EL 223 SECTION B-B O 19 7O 3O *O SO 10 . ?23 ; 2/650 •far for Poof dridqc ^ ^ i ,__^, _ p!r^a<'^^^^nrT-T-rir.jL^^sff^tff^^^^r^o ELEVATIONOVTLZT PIPE I I i i i i i i i ..< i i t i i SPILLWAY SILL £L: •3\6unite £/. 2/4.5 SECTION*. D-D \a 10 20 SCALE fH FEET }"rlo' CALAVEFlA DAM . 5AN DIEGO COUNTY '• Carlsbad Mutual Wafer Company,,. A.L.Sonderegge^'-,; O wner. -Sent /74-f Engineer^ \. STATE OF CALIFORNIA ' DEPARTMENT OF .PUBLIC WORKS DIVISION OF WATER RESOURCES APPLICATION NO-047 APPROVED ;; March 26,. 1942 •,vy I I I I I II i I I I I I I i lI i I I I 1 I I Calavera _LakeHydrograpnsof j.nf low tne routing aad_outflow^for studyobtained in Inflow hydrbgiJapR Outflow hydrograjbh i I I I I I i I I I i I I i i I i i i t I I I i I I I I I i . 5 AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE E- Cdtd Lu ;zfo E— 25- STATION, PERT SECTfON ^0, LOOKING UPSTREAM till i t liliiiiiiiiifititiiiiiiiiiii . 4 AQUA HEDIONDA CREEK AT RANCHO CARLSBAD CROSS SECTIONAL PROFILE E- o CO STATFON, FEET SECI'iON 21, LOOKING UPSTREAM LIST OF FIGURES Fig. 1. Calavera Dam Fig. 2. Hydrographs of inflow and outflow for Calavera Lake obtained in the routing study Fig. 3. Cross-sectional profile of Section 20 for Aqua Hedionda Creek Fig. 4. Cross-sectional profile of Section 21 for Aqua Hedionda Creek Fig. 5. Cross-sectional profile of Section 22 for Aqua Hedionda Creek Fig. 6. Cross-sectional profile of Section 23 for Aqua Hedionda Creek Fig. 7. Cross-sectional profile of Section 24 for Aqua Hedionda Creek Fig. 8. Cross-sectional profile of Section 25 for Aqua Hedionda Creek Fig. 9. Cross-sectional profile of Section 26 for Aqua Hedionda Creek Fig. 10. Cross-sectional profile of Section 27 for Aqua Hedionda Creek Fig. 11. Cross-sectional profile of Section 28 for Aqua Hedionda Creek Fig. 12. Cross-sectional profile of Section 29 for Aqua Hedionda Creek Fig. 13. Cross-sectional profile of Section 30 for Aqua Hedionda Creek Fig. 14. Cross-sectional profile of Section 31 for Aqua Hedionda Creek Fig. 15. Cross-sectional profile of Section 32 for Aqua Hedionda Creek Fig. 16. Cross-sectional profile of Section 33 for Aqua Hedionda Creek Fig. 17. Cross-sectional profile of Section 34 for Aqua Hedionda Creek Fig. 18. Cross-sectional profile of Section 35 for Aqua Hedionda Creek Fig. 19. Cross-sectional profile of Section 36 for Aqua Hedionda Creek Fig. 20. Cross-sectional profile of Section 37 for Aqua Hedionda Creek Fig. 21. Water-surface and bed profiles for Calavera Lake Creek through mobile home park based on restored channel Fig. 22. Water-surface and bed profiles for Aqua Hedionda Creek through mobile home park t i I i t I i i t i t i I I i I I i t i ft i ilfiJtiiJlJft; ng. 5 AQUA HEDIONDA CREEK AT RANCHO CARLSBAD CROSS SECTIONAL PROFILE E-[J Cd t-, &o 35 200 300 STATION, FEET SRCTION ZZ, LOOKING UPSTREAM I I I < t ' i < I ' I I I I i ) I i I i I I I 1 I i I I I i I I t i I i t j rig. 6 AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE 55 45 E- o 35 250 150 STATION, FEET '="7> f on raw; n I I I I I 1 I I I I I I I I I j i I I I I I I I i I i I i I til* 7 AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE 250 350 STATION, FEET SECTION 24, LOOKING UPSTREAM t i ft i ft i • i ft I i i i J i i i i i i l i I i i f i i i I J I I I AQUA HEDIONDA CREEK AT RANCHO CARLSBAD CROSS SECTIONAL PROFILE GO 40 -V- 30- 400 500 STATION, FEET SRCTION 25, LOOKING UPSTREAM till 11 i I i I i I i i i i I i i i i i i i I i I i I i I i g. 9 AQUA HEDIONDA CREEK AT RANCHO CARLSBAD CROSS SECTIONAL PROFILE BO Cd o 40 30- 6'iO STATION, FEET SECTION 26 LOOKING UPSTREAM I i I i • i I I l I i I i I i i I I i i i i I f I i i I i i i rig. 10 AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE E- C£l Cd 30- 550 (550 STATION, FEET SECTION 27, LOOKING UPSTREAM I I • I I I • I t I I I f I I J I 1 t I I 1 I I I I I i I I 1 i I i i t . 11 AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE 60 50- Ed 40- 30 «00 000 STATION, FEET SECTION 28 LOOKING UPSTREAM t i t i I i i f i ) t i * i i t i t i I I i t i I i i AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE 35- 400 GOO STATION, FEET SECTION 29, LOOKING UPSTREAM i i i i i I i i i i f t ; I i i l t I 1 I i t i i I I i I . 13 AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE 35- GOO ftOO STATtON, FEET SECTION 30 LOOKING UPSTREAM 1000 I I I I I i I 4 t < I i t t t ) E ! t i I 1 i 1 I i i i I I t I t ' K f I > . 14 AQUA HEDIONDA CREEK AT RANCHO CARLSBAD CROSS SECTIONAL PROFILE E- C£] Cd Du fr O 45 -J f-\ T3-" GOO flOO STATION, FEET SRCT[ON :3I, LOOKING UPSTREAM (000 iJlJftiiilitlflflt . 15 35- AQUA MEUIONUA CREEK AT RANCILO CAKLbUAU CROSS SECTIONAL PROFILE 700 900 1100 STATION, PEET SFKTFON 32, LOOKING UPSTREAM II II I I I I I I I I I I I I I I I I i I I I I I 1 I i I i ft I s i rig. 16 AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE 35- GOO fiOO tOOO STATION, FEET Sf'X.TfON 33, LOOKWC UPSTREAM till I i i i i r i i r i l 3 i i i i I I I I I i I i * ig. 17 35- AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE GOO ttOO 1000 STATION, FEET SECTION 34, LOOKING UPSTREAM 1200 I I t 1 I i I • i i i i i i fiiiiiiiiiiiiiiiiiii . 18 AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE 40- GOO «00 1000 STATION, FEET SECTION 35, LOQKTNC UPSTREAM iiftiijlililillt Iljlililllliililil ig. 19 Cd a 50 40 AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE GOO 000 1000 STATfON, FEET S'CCTFON 36, LOOKING UPSTREAM 1200 i j i i i ft i i ( i f i i i i i i i I i I i I i i till n«. 20 AQUA HEDIONDA CREEK AT RANG HO CARLSBAD CROSS SECTIONAL PROFILE 40- UOQ 1000 (ZOO STATION, FEET SECTION 37, LOOKING UPSTREAM 1400 iiiiiiiiiiiiftiiiiii I i I i I i i i I I I i i ) I . 21 CALAVERA LAKE CREEK -- DESIGN CONDITIONS WATER SURFACE AND CHANNEL-BED PROFILES CJ DISTANCE, IN 1000 FEET LOO-YEAR FLOOD n - WS 0 = CHANNEL BED f> i f i i i l I i i I I I 1 I J I 1 t i i I I I I I i I i t U- O 22 AQUA flEDl'ONDA CREEK - EXISTING CONDITIONS WATER-SURFACE AND CHANNEL-BED PROFILES DISTANCE, IN LOGO FEET 1.00-YEAR FLOOD w s CHANNEL BED I i I i I f I i I I I I I I l tliilililjlililiii i *««»»#«** *««»**»«»* »***«**»»«***«***«*#»»* * * FLOOD HYCRDGRAPH PACKAGE (HEC-1) * * FEBRUARY 1981 » * REVISED 02 AUG 88 * RUN DATE 07/01/1989 TIME 11:36:** * * **#**«**« **««**#**»********** ****»»***«** ««*e««#»****«*»*««»***»B»st?*«**«»***?s » « * U.S. ARMY CORPS OF ENGINEERS * * THE HrOROLOGIC ENGINEERING CEKTER * * tC9 SECOND STRE=T * * CAVIS, CALIFORNIA =5616 9 * C916) 551-17*5 * * * ***«******«««»»«**»******%$«***«*»*«**« X X X X X X XXXXXXX X K X X X X XXXXXXX X Xxxxx X X XXXXXXX xxxxx X X X X X X Xxxxxx xxxxx X XX X X X X XXX TMS PROGRAM REPLACES ALL PREVIOUS VERSIONS OF HEC-1 KNOWN AS HEC1 (JAN 73). HEC1GS, HEC10B, AND KEC1KW. THE DEFINITICNS OF VARIABLES -RTIHP- AND -RTIOR- hAVE CHANGED FROM THOSE USED WITH THE 1973-STYLE INPUT STRUCTUREThE DEFINITION OF -AH5KK- ON RM-CARO WAS CHANGED hITH REVISIONS DATED 28 SEP 81. THIS IS THE FORTRAN77 VERSIONNEV OPTIONS: OAHBREAK OUTFLOW SUBMERGENCE , SINGLE EVENT DAMAGE CALCULATICN, OSSIHRITE STAGE FREQUENCY,OSSIREAD TIME SERIES AT DESIRED CALCULATICN INTERVAL LOSS RATE:GREEN AND AMPT INFILTRATIONKINEMATIC WAVE: NEW FINITE DIFFERENCE ALGORITHM , HEC-1 INPUT PAGE 1 LINE i 2 3 5 6 7 B 9 10 11 12 13 1* 15 16 17 18 19 20 ID 1. ID ID ID ID IT 10 KK KM IN PB PI PI PI PI PI 6A LS UD KK KM ,6.>8 .9. . ... .10 ^ > DRAINAGE STUDY FOR NE QUACRANT OF CARLSBAC FCft ULTIMATE CONDITIONS OF WATERSHED DEVELOPMENT Z4-HOUR STORM, 100-YEAR EVENT ZONES 7, 1* AND 15 5 300 5 CL Al RUNCFF FRDM CALAVERA LAKE BASIN Al 30 5.10 .009 .007 .009 .009 .016 .017 .02 .023 .0*1 .027 .023 .021 .016 .015 .01* .015 .011 .01 .009 .009 0 .014 .082 .01 .01 0.7* .011 .03 .02 .012 .C09 .009 .0*5 .019 .013 .009 .011 .067 .017 .01 .01 .012 .068 .016 .01 .009 .013 .096 .018 .009 90o.*s CL A2 RUNCFF FRCM CALAVERA LAKE BASIN A2 I i i I t i I I I I I I i i I i r i t i t J I I i i I i I i t i i i i i I 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 LIKE 48 49 50 51 52 S3 54 55 56 57 58 59 60 el 62 (3 £4 45 66 BA LS UD KK KM HC KK KM RS RC RX HY KK KM PB BA LSuo KK KM MC KK KM PB 6* LS UD 10 KK KM HC KK KM RS RC RX RY KK KM PB BA LS UO KK KH MC KK 0.21 90 0.23 PT. 1 C:ieiNE FLOWS CF Al AND A2 2 CL A3 CHANNEL ROUTING THRCUGH CALAVERA LAKE BASIN A3 1 STOR -1 0*022 0.022 0.022 4200 0.012 465 475 485 495 505 515 525 535 355 350 345 340 340 345 350 355 CL A3 RUNOFF FROM CALAVERA LAKE BASIN A3 5.0 0.46 89 0.25 PT. 2 CCHBINE FLOW CF A3 WITH ROUTED FLOW 2 CL A4 RUNOFF FROM CALAVERA LAKE BASIN A4 5.10 0.68 90 0.49 HEC-1 INPUT PT. 2 COMBINE FLOWS CF BASINS A3 AND £4 2 CL AS CHANNEL ROUTING TMRCUGH CALAVERA LAKE BASIN AS 1 STOR -1 0.022 0.022 0.022 3200 0.014 465 *75 485 495 507 517 527 537 275 270 265 260 260 265 270 275 CL *5 RUNCFF FROM CALAVERA LAKE SASIN AS 4.9 0.20 87 0.19 CL AS COMBINE FLOW OF A5 WITH ROUTED FLOW 2 CL A6 PAGE .9 10 tJtiiiiiftilltJiifjiifitiftitiiiiilii' (7 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 66 87 88 89 LINE 90 91 92 S3 94 95 S6 97 S3 99 100 101 102 103 104 105 1C6 1C7 108 109 110 111 112 113 KM PB BA LS UO KK KN HC KK KM RS RC RX RT KK KM PB 8A LS UO KK KM HC KK KM PB BA LS UO KK KM HC KK KM PB 8A LS UO KK KM HC KK KM KQ RS SA SE RUNCFF 4.9 0.50 0.25 PT. 3 COMBINE 2 CL A7 CHANNEL FROM CALAVERA LAKE BASIN A6 87 FLOWS CF BASINS AS AND A6 ROUTING THROUGH CALAVERA LAK£ 3ASIN A7 1 STOt -I 0.030 0. 450 245 CL A7 RUNOFF 4.9 0.20 0.21 CL AT COMBINE 2 CL AB RUNCFF 4.9 0.29 0.26 PT. 4 COMBINE 2 CL A9 RUNCFF 4.75 0.31 0.18 CL A9 COMBINE 2 PT. 5 STORAGE 3 030 0.030 2700 0.010 465 480 495 515 530 545 560 240 235 230 230 235 240 245 FROM CALAVERA LAKE BASIN A7 88 FLOM OF A7 WITH ROUTED FLOW HEC-1 INPUT FROM CALAVERA LAKE BASIN AS 88 FLOWS CF BASINS A7 AND AS FROM CALAVERA LAKE BASIN A9 90 FLOWS CF BASINS A7. AS, AND A9 ROUTING IN CALAVERA LAKE 2 1 ELEV 209.0 21 24 27 30 33 35 38 39.5 41 43 208 210 212 214 216 217 218 219 230 221 PAGE tJtitiiilitJiiiitilJilifiitlliiii** 114 SS 216.5 150 2.64 1.5 US 116 117 113 119 120 121 122 123 124 12S 126 127 128 129 130 131 132 133 134 135 LIKE 136 137 138 139 140 1*1 142 143 144 145 146 147 148 149 150 151 152 153 IS* 155 156 157 158 159 KK KM RS RC RX RY KK KM P6 BA IS UD KK KM HC KK KM PB BA LSuo KK K.H HC KK KM RK KK KM PB BA LS UO KK KM HC KK KH PB BA LS UD KK KMpa CL A10 CHANNEL ROUTING THROUGH CALAVERA LAKE SASIN A1Q 1 STOR -1 0.035 0. 450 165 CL A10 RUKGFF 4,5 0.36 0.19 PT. 6 0*5 0.035 3600 0.027 *65 4BO *95 515 530 545 560 160 155 150 150 155 160 165 FROM CALAVERA LAKE BASIN »10 87 COMBINE FLOhS CF BASIN AID hITH ROUTED FLCW 2 CL All RUNGFF 4.75 0.23 0.21 PT. 6 COMBINE 2 CL A12 CHAKNEL 3100 0. CL A12 RUNCFF 4.5 0.3* 0.23 PT. 8 COMBINE 2 CL LI RUNOFF *.9 0.49 0.35 CL L2 RUNCFF *.9 PROM CALAVERA LAKE BASIN All 86 HEC-1 INPUT FLOWS OF BASINS A10 AND All ROUTING THROUGH CALAVERA LAKE EASIN A12 007 0.035 20 3 FROM CALAVERA LAKE BASIN A12 87 FLOWS CF BASIN A12 hITH ROUTED FLOW FROM CALAVERA LAKE BASIN LI 66 PROM CALAVERA LAKE 8ASIN L2 PAGE 10 t 4 I i I i i I i I i i i 160 161 164 165 146 167 168 169 170 171 172 173 17* 175 176 177 LIKE 178 179 160 181 162 183 IB* 185 166 187 188 189 ISO 191 192 195 1S6 157 198 199 200 201 202 203 204 205 206 BA LSno KK KK HC KK KHas RC RX RT KK KM P6 5A LS UD KK KN HC KK KH HC KK KM RS RC RX RT KK KM RS RC RX RT KK KM PB BA LSuo 0.4B 0.27 PT. 7 COMBINE 2 CL L3 CHANNEL B6 FLOWS CF BASINS LI AND L2 ROUTING THROUGH CALAVERA LAKE SASIN L3 1 STOR -1 0.030 0. 450 115 CL L3 RUNCFF 4.75 0.39 0.30 PT. 8 COMBINE 2 PT. 6 COMBINE 2 CL '12 CHANNEL 040 0.030 4700 0.036 465 480 495 505 520 535 550 110 105 100 100 105 110 115 FROM CALAVERA CAKE BASIN L3 86 HEC-1 INPUT FLOWS OF BASIN L3 WITH ROUTED FLOW FLQMS CF BASIN A12 hITK ROUTED FLOW FROM L3 ROUTING THROUGH CALAVERA LAKE BASIN A12 1 STOR -1 O.C30 0. 482 52 CL *13CHANNEL 028 0.030 1200 0.007 488 494 500 506 512 518 524 48 44 40 40 44 48 52 ROUTING THROUGH CALAVERA LAKE BASIN A13 1 STOR -1 0.030 0. 462 47 ACUAUA HUNCFF 5.50 6.50 1.02 028 0.030 2050 0.004 488 494 500 506 512 516 524 43 39 35 35 39 43 47 FROM AQUA HEDIONCA BASIN UA 91 PAGE 10 KK AQUAUB KM RUNCFF FROM AQUA HEDIONDA BASIN UB PB 5.4 BA 3.00 LS 91 iiilititifift!t;i:!!ifeitll*liftJft*iiti 207 UO 0.76 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 LXhE 223 224 225 226 227 228 229 220 231 232 233 234 225 236 237 23B 239 240 241 242 243 244 245 246 247 248 249 250 251 252 KK KM HC KK KM RS RC RX RY KK KM PB 6* LS UD 10. KK KM HC KK KN PB BA LS UD KK KN PB BA LS UD KK KN HC KK KM RK KK KM PB BA LS UD KK KM HC PT 10 COMBINE FLOWS FROM AQUA BASINS C* AND UB 2 AQLJAUF ROUTING THROUGH OANKEL IN BASIN UF 1 STQR -1 0.030 0.040 0.030 7300 0.0075 600 505 965 1000 10ZO 1040 1100 1315 350 325 320 318 319 320 325 350 AQUAUF RUNOFF FROM AQUA HEDIONDA BASIN UF 5.2 1.11 89 0.46 HEC-1 INPUT .1 2 -.3 4 5 6 7 8 9 10 AQUAUF COMBINE FLOWS PROM (QUA HEDIONCA BASIN UF AND ROUTED FLOW 2 AQUAUE RUNOFF FROM AQUA HEOIONDA BASIN UE 5.0 0.242 B8 0.17 AQUAUG RUNOFF FROM AQUA HECIONCA BASIN UG 5.1 1.15 89 0.41 PT 11 COMBINE FLOWS FROM BASINS UE, UF. AND UG 3 AQUA G ROUTING THROUGH CHANNEL IN BASIN G 8200 0.022 0.033 0 0 20 3 AQUA G RUNOFF FROM AQUA HEDIDNOA BASIN G 4.9 0.51 67 0.38 PT 12 COMBINE FLOW FRCM SiSIN G WITH ROUTED FLOW 2 PAGE litiKllitatiftitiiitiliiiiililiiiiii £53 254 255 256 2572sa 259 2«0 261 262 263 2«4 LIhE 2(5 266 267 268 269 2TO 271 272 273 274 275 276 277 278 279 260 281 282 283 264 285 266 287 288 289 290 291 292 293 294 295 296 297 KK KM PB 6A LS UO KK KH ft B* LS UO 10. KK KM HC KK KH RS RK KK KM PB BA LS UO KK KM HC KK KH RK KK KM ft BA LS UO KK KM HC KK KN HC KK KH AOUAUC RUNOFF FROM AQUA HEDIONC* BASIN UC 5.25 1.65 90 0.60 AQU*UD RUNOFF FROM AQUA H£DIONCA BASIN UD 2.65 0.42 B8 0.22 HEC-1 INPUT PT 13 COMBINE FLOWS FROM UC AND UD 2 AQUA H ROUTING THROUGH CHANNEL IN BASIN H 10 STD8 -1 0 2300 0.018 0.032 0 0 20 3 AQUA H RUNCFF FROM ACUA HEDIONCA BASIN M 4.9 0.35 88 0.20 PT 14 COMBINE FLOW FROM BASIN H WITH ROUTED FLCW 2 AQUA F ROUTING THROUGH CHANKEL IN BASIN F 4200. 0.022 0.033 0 0 20 3 AQUA F RUNCFF FROM AOUA hECIONDA BASIN F 4.9 0.96 91 0.17 PT 12 COMBINE FLOW FROM BASIN F WITH ROUTED FLOW 2 PT 12 COMBINE FLOW FROM BASIN G WITH ROUTED FLOW 2 AQUA E ROUTING THROUGH CHANNEL IN BASIN E PAGE 10 i i 2S8 RK 4200 0.010 0.035 0 0 20 2 299 KK AQUA C 3CO KM RUNOFF FROM AQUA HECIDNCA BASIN E 3C1 PB 4.75 302 BA 0.58 303 LS 86 304 UD 0.23 MtC-1 INPUT PAGE 8 LIKE 10 1 2 3 4 5 6 7 8 9 10 305 KK PT IS 306 KN COMBINE FLOW FROM BASIN E UlTH ROUTED FLDU 30T MC 2 308 KK AQUA D 309 KM ROUTING THROUGH CHANNEL IN BASIN D 320 RK 1800 0.010 0.035 0 0 25 2 311 KK AQUA 0 312 KM RUNOFF FROM AQUA HEDIONDA BASIN D 313 BA 0.28 314 LS 86 315 UD 0.16 316 KK PT 16 317 KM COMBINE FLOW FROM BASIN 0 WITH ROUTED FLOW 318 HC 2 319 KK AQUA C 320 KM RUNOFF FROM AQUA HECIONDA BASIN C 321 BA 0.302 322 LS 90 323 UD 0.12 32* KK PT 17 325 KM COMBINE FLOW FROM BASIN C WITH ROUTED FLOW 326 HC 2 327 KK AQUA B 328 KM ROUTING THROUGH CHANNEL IN BASIN B 329 RK 3600 0.007 0.030 25 1.5 330 KK AQUA B 331 KH RUNOFF FROM AQUA HECIONCA BASIN B 332 PB 4.50 333 BA 0.25 33+ LS 87 335 UD 0.24 336 KK PT IB 337 KM COMBINE FLOK FRCM BASIN B liITH ROUTED FLOW 338 HC 2 339 KK PT 18 340 KM COMBINE FLDNS FROM AQUA HEDIONOA CREEK AND CALAVERA CREEK 341 HC 2 i i k i I i i i t i i i i i i I i i i i i t * « * * * * » * V 342 3*3 344 345 346 347 LIKE 348 349 350 351 352 353 35* 355 356 357 358 359 360 361 362 363 3(4 365 366 367 368 fttt*A**4&A*iAflAfiA*A**ft***»****<*:»****» * v ww KK KM PB BA LS UD KK KM HC KK KM PB BA LSuo KK KM HC KK KM BA LS UO KK KM HC ZZ A A ft A ft ft****** FLOOD HYCRQGRAPH PACKAGE FEBRUARY REVISED 02 HUN DATE 07/01/1989 1961AUG ee TIME CL A13 RUNCFF FRCM CALAVERA LAKE BASIN A13 4.5 0.17 87 0.15 McC-1 INPUT PT IB COMBINE FLOWS OF BASIN A13 hITH fiOUTEO FLOW 2 AOUA1* RUNCFF FROM BASIN A14 *.5 0.43 87 0.18 PT 18 COMBINE FLOWS CF BASIN A14 blTH ROUTED FLOW 2 AQUA A RUNCFF FROM AQUA HEDIQNDA BASIN A 0.283 86 0.10 PT 19 COMBINE FLOWS OF BASINS A AhD B 2 AAAAflAAAAAAA ftftftftftAttfrttfifiAbttft19 * « * * ** ¥¥¥W *******^*V**W¥*-¥' * * CHEC-1) * * U.S. ARMY I * * THE HYDROLDG: * * 609 : * * DAVISt 1 11:36:44 * * C91< * * #***#*««* *«*«*««* **«****«**«**»**»#»«*«** *«»«»««*#«#***«: PAGE 609 SECO\0 STREET S, CALIFORNIA 95 C916) 551-1748 6 10 DRAINAGE STUDY FOR NE OUADRAKT CF CARLSBAD FOR ULTIMATE CONDITIONS CF WATERSHED DEVELOPMENT 24-HCUR STOSM, 100-YEAR EVENT ZONES 7, 14 AND 15 OUTPUT CONTROL VARIABLES IPRNT 5 PRINT CONTROL IPLOT 0 PLOT CONTROL CSCAL 0. HYDROGRAPH PLOT SCALE i I 1 t I I i I i I i ft i I } E IJlitJIIIflllllilJ IT HYCROGRAPM TIME DATA NMIN IDATE ITIME NO NODATE NCTIME ICENT COMPUTATION TOTAL 5 1 0oooc 300 2 0 0055 19 INTERVAL TIME BASE MINUTES IN COMPUTATION INTERVAL STARTING DATE STARTING TIME NUMBER OF HYDR03RAFM ENCING DATE ENDING TIME CENTURY HARK .08 HOURS 24.92 HOURS CRDINATES ENGLISH UMTS DRAINAGE AREA PfiECIPITATION DEPTH LENGTH. ELEVATION FLOW STORAGE VOLUME SURFACE AREA TEMPERATURE SJUARE MILES INCHES FEETCUBIC FEET PER SECONDACRE-FEET ACRESDEGREES FAHRENHEIT *«* »** *#* »** **# **» «***** ****** #** »** **» ****** *** *** *** ***»** 108 KK 110 KO 111 RS 112 SA S£ ************** * * * PT. 5 * * » ************** OUTPUT CONTROL VARIABLES IPRNT 3 PRINT CONTROL IPLCT 2 PLOT CCNTRCL CSCAL 0. HYDROGRAPH PLOT SCALE HTORCCRAFH BOLTING DATA STORAGE ROUTING NSTPS ITYP RSVCIC X AREA 1 NUMBER OF SU6REACHES ELcV TYPE CF INITIAL CCKDITION 209.00 INITIAL CCKOITION .00 WORKING R AND 0 COEFFICIENT 21.0 ELEVATION 208.00 24.0 210.00 27.0 212.00 30.0 214.00 33.0 35.0 38.0 39.5 41.0 43.0 216.CO 217.00 218.00 219.00 220.00 221.00 114 SS SPILLWAY CREL SFWIO COOH EXPU 216.50 SPILlhAY CREST 5LEVATICN 150.00 SPILLWAY WIDTH 2.64 WEIR COEFFICIENT 1.50 EXPONENT CF HEAD *** COMPUTED STC8AGE-ELEVATIGN CATA I I I I I i I I i i I ft i i I I i i I i iiliiliiilititi STORAGE ELEVATION CUTFLOW ELEVATION CUTFLCW ELEVATION STORAGE OUTFLOW ELEVATION STORAGE OUTFLOW ELEVATION STORAGE OUTFLOW ELEVATION *** .00 208.00 .00 206.00 472.52 217.63 .00 .00 208.00 24*. 56 81.03 216. 85 325.12 1565.33 219.00 *** 44.97 210.00 .00 2K.50 648. IB 217.89 44.97 .00 210.00 249. ae 140.01 217.00 333.93 1776.62 219.22 *** 95.94 153.91 215.69 212.00 214.00 216.00 COMPUTED CUTFLCW-ELEVf; .65 5.19 17. JO 216.51 216.56 216. £3 862.73 1120.06 1424.06 218.18 216.50 218.65 COMPUTED STCflAGE-OUTFLGh-EL: 95.94 152.91 215.89 .00 .00 .00 212.00 214.00 216.00 256.25 263.72 272.34 222.33 331.87 472.52 217.18 217.39 217. t3 350.10 365.37 367.65 2187.61 2592.97 2654.95 219.63 220.00 220. C6 *#* *=» 249.88 2S6.37 325.12 365.37 407.36 217.00 218.00 219.00 220.00 221.00 ;N CATA 41.49 81.03 140.01 222.33 331.87 216.72 216.85 217.00 217.13 217.39 1776.62 2187.61 2654.95 3184.51 37 GO. 19 219.22 219.63 220.06 220.51 221.00 VATIQN CATA 232.63 233.11 234.53 236.90 240.24 .00 .65 5.19 17.50 41.49 216.50 216.51 216.56 216.63 216.72 282.17 286.37 293.26 305.56 319.10 648.16 727.50 862.73 1120.06 1424.06 217.89 218.00 218.18 218.50 21B.8S 386.70 407.36 31E4.51 3780.19 220.51 221.00 HTOROGRAPH AT STATION PT. 5 PEAK FLOW TIME (CFS) CHR) 1171. 11.08 PEAK STORAGE TIME (AC-FT) CHR) 309. 11.08 PEAK STAGE TIME <FEET> CHH) 218.56 11.08 CCFS) (INCHES) UC-FT> 6-HR 613. 1.578 304. 6-HR 279. 6-HR 217.81 CUMULATIVE ARE* « 0. 400. 0. 0. DAHRMN PER 10000 11- .- <I) INFLOW, CO} BOO. 1200. 0. 0. MAXIMUM AVERAGE FLCW 24-HR 72-HR 2*. 246. 237. 2.532 2.532 487. 487. MAXIMUM AVERAGE STORAGE 24-HR 72-HR :-. 164. 176. MAXIMUM AVERAGE STAGE 24-HR 72-HR 2.. 214.66 214.45 : 3.61 SO MI STATION PT. OUTFLOW 1600. 2000. 0. 0. 0. 0. 92-t-R 237. 2.532 487. 92-hH 178. 92-HR 14.45 5 0. 0. 0. 0. 0. 0. CS) STORAGE 100. 200. 300. 400. 0. 0. I I • I I I I i i I i i I I i i i i ilililiilliiitj 10005 10010 10015 10020 10025 10030 10035 10040 10045 10050 10055 10100 10105 10110 10115 10120 10125 10130 10135 10140 10145 10150 10155 10200 10205 10210 10215 10220 10225 10230 10235 10240 10245 10250 1025S 10300 10305 10310 10315 10320 10325 10330 10335 10340 10345 10350 10355 10400 10405 10410 10415 10420 10425 10430 10435 10440 10445 10450 10455 10500 21 31 41 51 61 71 81 91 • 4 101 121 131 141 151 161 1TI 101 4 4 191 201 221 231 241 251 261 271 281 291 301 311 . . 321 331 341 351 361 371 361 391 401 411 .... 421 431 441 . . 451 461 471 481 4%I • 501 511 ,. 521 531 541 5501 5601 5701 5801 5901 6001 6101 . S . S. s. s 4 S 4 S. s. s. s 4 S. s. s. s. s. s .. s. s 4 S 4 . s. s .. s 4 S. s 4 S 4. s. $ 4 S . 4 S 4. s. s .. s. s 4 S. s 4 S. s 4 S 4. s .. s .. s. s 4 S. s. s . 5 . 4 S 4. s. s. s 4 S 4. s . 4 * . 4 5 4 . • * 4 . 4 4 . 4 S 4 . . 4 . . . 4 4 4 S 4 . . 4 4 S 4 I I I I I I I I I fciiiiiliiiiitililJiiilt 10505 10510 10515 10520 10525 10530 10535 10540 10545 10S50 10555 10600 10605 10610 10615 10620 10625 10630 10635 10640 10645 106SO 10655 10700 10705 10710 10715 10720 10725 10730 10735 10740 10745 10750 10755 10800 10805 10810 10815 10820 10825 10830 10835 10840 10845 10850 10655 10900 10905 1091 0 10915 10920 10925 10930 10935 10940 10945 10950 10955 11000 620Z . . . . . . S 630Z . . . . . . S 640! . . . . . . S 650 Z . . . . . S 660 Z . . . . . . S 670 Z . . . . . S 680 Z. . . . . .S. 690 I . . . . . S . 700 Z . . . . . S 72C I . . . . . . S 730 . . . . . . S 740 . . . . . . S 750 . . . . . . S 760 . . . . . .S. 7 TO . . . . . . S 780 . . . . . .S. 790 Z . . . . S 800 Z . . . . S 620 Z . . . . S 830 Z . . . . S 840 Z . . . . S 850 Z . . . . S 860 Z . . . . S 670 Z . . . . S 880 Z . . . . S B9Q I . . . . S 900 Z . . . . S 920 Z . . . . S 930 Z . . . . . S 940 I . . . . . S 950 I . . . . . 5 960 I . . . . . S 970 I. . . . . S 980 Z. . . . . S . 990 Z . . . . . S . 1000 .Z . . . . S . 1020 . Z . . . S . 1030 I . . . S . 1040 Z . . . . S . 1050 Z . . . . S. 1060 Z . . . . S. 1070 Z. . . . . S 1080 .Z . . . . S 1090 . . I . . . .S 1100 . Z . . . . S 1120 . . Z . . . . . S 1130 . . -Z . . S 1140 . . . Z . . . S 1150 . . Z . . S 1160 . . .1. . . .S. 1170 . . . Z . . . . S . 1180 . . . Z . . . S. 1190 .Z . . . S 1200 . . . . 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ID 10 .10 s .$ .s .s .. s .s .s .ss . ssssss .sss 5ssssss 5s s 5 * » 5 » * * * Sss .sss s .sssssss .ssssss .s .s .s .ss .s lifiliiitiiiiii 1 i I I i t i I i i I i i i 12005 12010 12015 12020 12025 12030 12035 12040 12045 12050 12055 12100 12105 12110 12115 12120 12125 12130 12135 12140 12145 12150 12155 12200 12205 12210 12215 12220 12225 12230 12235 12240 12245 12250 12255 12300 12305 12310 12315 12320 12325 12330 12335 12340 12345 12350 12355 20000 20005 20010 20015 20020 20025 20030 20035 20040 20045 20050 20055 242. 243. 244. 245, 246, 247. 248. 249. 250. 251, 252. 253. 254. 255. 256. 257. 258. 259. 260. 261. 262. 263. 264. 265. 266. 267. 268. 269. 270. 271. 272. 273. 274. 275. 276. 277. 278. 279. 280. 281. 282. 263. 284. 285. 286. 287. 286. 269. 290. 291. 292. 293. 294. 295. 296. 297. 298. 299. 10 10 10 10 10 10 10 10 10. I1IIII 10 10 10 10 10 10 10 10 I t J i I j i i i OPERATION HYODOGRAPH AT HYOROGRAPH AT 2 COMBINED AT ROUTED TO HTOROGRAPH AT 2 COMBINED AT HYDROGRAPH AT 2 COMBINED AT ROUTED TO HYDROGRAPH AT 2 COMBINED AT HYORDGRAPH AT 2 COMBINED AT ROUTED TO HYDROGRAPH AT 2 COMBINED AT STATIOK CL Al CL A2 PT. 1 CL A3 CL A3 PT. 2 CL A4 PT. 2 CL AS CL AS CL AS CL A6 PT. 3 CL *7 CL A7 CL A7 PEAK FLOW 389. 115. 499. 498. 251. 742. 355. 1094. 1092. 98. 1185. 242. 1421. 1419. 100. 1514. TIPE OF PEAK 10.25 10.06 10.25 10.33 10.06 10.17 10.33 10.25 10.25 10.08 10.25 10.08 10.25 10.25 10. OB 10.25 FLOJ IS Ct-IC FEET PER SECOND TIHE IN HOURS. AREA IN SQUARE MILES AVERAGE FLCW FOR HAXIfUH PESIOC 6-hOUR 24-HOUR 72-hOUR 193. 55. 246. 247. 119. 366. ITT. J44, 46, SS9. 11*. 704. 703. 47. 750, 79. 22. 101 101. 49. 149. 72. 222. 221, 19, 2*0. 47. 286, 266. 19. 305, 76, 22, 97. 97. 47. 144. 70. 213, 213, 18. 231. 45. 276. 275. 19. 29*. BASIN MAXIMUM TIME DF AREA STAGE MAX STAGE .74 .21 .95 .95 .43 1.43 .68 2.11 2.11 .20 2.31 .50 2.81 2.61 .20 3.01 342.75 263.73 10.33 10.25 234.22 10.25 I I j i i jilt HTOROGBAPH AT 2 CCM8INED AT HTDROGRAPH AT 2 CCHBINEO AT ROUTED TO ROUTED TO CL AS PT. 4 CL A9 CL A9 PT. S CL A10 144. 1C.03 1655. 10.25 158. 1603. 1171. 10.00 10.17 11.08 1166. 11.IT HTDROGRAPH 2 COMBINED HTDROGRAPH 2 CCHBINEO ROUTED TO HYDROGRAPH 2 COMBINED HY080GRAPH HYDROGR1PH 2 COMBINED ROUTED TD HYDRDGRAPH 2 COMBINED AT AT *T AT AT AT AT AT »T AT AT CL PT CL PT CL CL PT CL CL PT CL CL A10 . 6 All . 6 U2 A12 . 8 LI L2 . 7 L3 L3 158. 1236. 105. 1287. 128S. 148. 1353. 226. 225. 450. 447. 174. 10 11 10 11 11 10 11 10 10 10 10 10 .08 .08 .08 .08 .17 .08 .17 .17 .08 .17 .25 .17 PT. 8 620. 10.25 68. 619. 74. 893. 613. 611. 74. £56. 49. 687. 6B7. 69. 731. 109, 107. 215. 215. 83. 296. 28, 333. 30. 363. 246. 244, 30. 274, 20. 294. 293. 28. 321, 43. 88. 87. 34. 121 27. 320. 29. 350. 237. 235. 29. 264. 19, 284, 282. 27. 309. 43. 42. 85. 84, 33. 117. .29 3.30 .31 3.61 3.61 3.61 .36 3.97 .23 4.20 4.20 .3 + 4.54 .49 ,48 .97 .97 .39 1.36 216.56 153.62 102.50 11. 08 11.17 10.25 i I I I i I i i i i I i i i i 2 CCHBINED AT ROUTED TO ROUTED TO PT. 8 CL A12 CL 1739. 11.00 1739. 11.00 1738. 11.00 1C01, 1001. 1001. 442. 4A2. 4*1. 426. 426. 424. 5.90 5.90 5.90 HYDflOGRAPH AT HYOROGBAPH AT 2 COMBINED AT ROUTED TO HYDHOGRAPH AT 2 COMBINED AT HVDRDGRAPH AT HYDBOGRAPH AT 3 CCHBINEO AT ROUTED TO MYORDGRAPH AT 2 CCMBINEO AT NYDfiOGRAPH AT HfDfiOCRAPH AT 2 COMBINED AT ROUTED TO AQUAUA AQUAUfl PT 10 AQUAUF AQUAUF AQUAUF AQUAUE AOCAUG PT 11 AQUA G AQUA G PT 12 AQLAUC AQLAUD PT 13 AQUA H 3364. 1618. 4952. 4895. SB3. 5976. 125. 596. 5958. 5956. 240. 6153. 672. 100. 966. 965. 10.92 10.67 10.75 10.92 10.33 10.83 10.00 10.25 10.75 10.83 10.25 10,75 10.50 10.08 10.50 10.50 1680. 654. 2733. 2727. 289. 3012. SB. 292. 3358. 3357. 117. 3473. 445. 46. 491. 491. 765. 346. 1113. 1103. 118. 1220. 24. 119. 1363. 1357. 47. 1404. 181. 19. 200. 200. 737. 335. 1C72. 1C62. 113. 1175. 23. 115. 1213. 1307. 46. 1353. 174. 18. 193. 192. 6.50 3.00 9.50 9.50 1.11 10.61 .24 1.15 12.00 12.00 .51 12.51 1.65 .42 2.07 2.07 47.72 43.75 323.94 11.00 11.00 10.92 i I i I t i i t i I i i i I j HYDROSRAPH AT 2 COMBINED AT ROUTED TO HYDROGRAPH AT 2 COMBINED AT 2 CCMBXNEO AT ROUTED TO MTOROGRAPH AT 2 COMBINED AT ROUTED TO MTOROG8APH AT AQIA H PT 14 AQUA F AQUA F PT 12 PT 12 AQUA E AQLA E PT 15 AQUA 0 AQUA D 176. 1125. 1123. 519. 1584. T597. 7589. 263. 7809. 7602. 129. 10.08 10.50 10.53 10.00 10.50 10.67 10.67 10.03 10.67 10.67 10. DO 2 COMBINED AT HYOROGRAPH AT 2 COMBINED AT ROUTED TO HVOROGRAPH AT 2 COMBINED AT 2 COMBINED AT HYDROGRAPH AT 2 COMBINED AT PT 16 AQIA C PT 17 AQl. A fl AQUA B PT 18 PT 16 CL A13 PT 16 7896. 10.67 155. 10.00 7994. 10.67 7999. 10.67 108. 10.06 8080. 10.67 9682. 10.75 75. 9726. 10.00 10.75 573. 573. 245. 816. 4260. 4279. 124. 4*01, 4401. 60. 4460. 72. 4530. 4529. 51. 4579. 5565. 35. 5599. 3*. 233, 232, 100. 333. 1737. 1732. 50. 1783, 1781, 24. 1605. 30, 1835. 1630. 21 1851, 2292, 14. 2306. 32, 225, 224 97. 320. 1(73. 1669, 49, 1717. 1715. 23. 1739, 26. 1767, 1763. 20. 1783. 2207, 14. 2221, .35 2.42 2.42 .96 3.38 15.89 15.89 .58 16.47 16.47 ,28 16.75 .30 17.05 17.05 .25 17.30 23.20 .17 23.37 i i i i 1 J i I I i I i HYQROGRAPH AT AQUA14 2 CCMBINEO HYDROGRAPH 2 CCMBINED AT AT AT PT AQUA PT 18 A 19 169. 9946. 123. 9910. 10. 10. 10. 10. 08 75 00 75 88. 568* 56 5738 36. 2342. 23 2364. 34. 2255. 22. 2277. .43 ::.BO .28 14.09 ISTAQ ELEMENT DT SUMMARY OF KINEMATIC HAVE fiCUTING CFLOW IS DIRECT RUNOFF WITHOUT BASE FLGU) INTERPOLATED "3 COMPUTATION IN PEAK TIME TO VOLUME DT PEAK TIME TO PEAK PEiK CHIN) CCFS) CMIN) (IN) CMIN) CCFS) CHIN) CL A12 3 .41 1286.38 669.23 2.59 5.00 1285.43 670.CO CONTINUITY SUMMARY CAC-FT) - INFLOW- 583.855 EXCESS- .000 OUTFLOW- 580.710 BASIN STORAGE' 3, •QUA C 3 .29 5958.28 649.41 4.21 5.00 5956.07 650.00 CONTINUITY SUMMARY CAC-FT) - INFLOW- 2703.925 EXCESS- .000 OUTFICU- 2691.652 BASIN STORAGE* 12, AQUA H 3 .50 966.25 631.98 3.59 5.00 965.39 630.GO CONTINUITY SUMMARY CAC-FT) - INFLOW* 396.855 EXCESS- .000 OUTFICW- 396.087 BASIN STORAGE- AQUA F 3 .52 1125.01 633.5* 3.57 5.00 1122.97 635.:0 CONTINUITY SUMMARY CAC-FT) - INFLOW- 462.738 EXCESS- .000 OUTFLOW- 461.177 BASIN STORAGE- 1, AOUA E 3 .25 7596.41 642.32 4.05 5.00 7589.40 640.10 CONTINUITY SUMMARY CAC-FT) - INFLOW- 3445.366 EXCESS- .000 OUTFLOW- 3436.139 BASIN STORAGE- 9, AQUA 0 3 .23 7808.85 640.92 4.02 5.00 7801.5? 640.CO CONTINUITY SUMMARY CAC-FT) - INFLOW- 3535.906 EXCESS" .000 OUTFLCW- 3532.033 BASIN STORAGE- 3, AOUA B 3 .21 7993.59 £42.08 3.99 5.00 7989.05 640.CO CONTINUITY SUMMARY CAC-FT) - INFLOW- 3639.068 EXCESS- .CCO OUTFLCW" 3630.013 BASIN STORAGE* 8, VOLUME CIN) 2.59 ,073 PERCENT ERROR* .012 4.20 ,457 PERCENT ERROR- -.007 3.59 ,747 PERCENT ERROR* .005 3.57 ,597 PERCENT ERROR" -.008 4.05 .098 PERCENT ERROR* .004 4.02 .568 PERCENT ERRCR- .009 3.99 ,790 PERCENT ERROR- .007 *** NORMAL EKD CF MEC-1 *** I i i i i I i i i***»*»*****»***»*»»******»**»»«*********** FLOOD MYCROGRAPH PACKAGE (HEC-1) * FEBRUARY 1981 » REVISED 02 AUG 86 * v RUN DATE 07/01/1989 TINE 11122:44 ft ***.»********* ************«***»*»****»**>* «s**«B***»«««»#«>#*4******************* * * 4 U.S. ARMY CORPS OF ENGINEERS * V THE HTDRCLOGIC ENGINEERING CENTER * * £09 SECOND STREET ** DAviSt CALIFORNIA 9S616 * * (916) 551-17*8 * * * *************************************** xxxxxxx xxxxx X X X Xxxxxxxx X X X X X X X X xxxx X Xxxxxxxx X X X X X X Xxxxxx xxxxx XX X X X X XXX THIS PROGRAM REPLACES ALL PREVIOUS VERSIONS CF HEC-1 KNOWN AS HEC1 (JAN 73), HEC1GS, HEC1DB, AND HEC1KW. THE DEFINITIONS OF VARIABLES -RTIMP- AND -RTIOR- HAVE CHANGED FROM THOSE CSEQ WITH THE 1973-STYLE INPUT STRUCTURE,ThE DEFINITION OF -AfSKK- ON RM-CARO WAS CHANGED WITH REVISICNS DATED 28 SEP 81. THIS IS THE FORTRAN?? VERSIONNEW OPTIONS: OAMBREAK OUTFLOW SUBMERGENCE » SINGLE EVENT CAMAGE CALCULATION, DSS!WRITE STAGE FREQUENCT,OSSJREAD TIME SERIES AT DESIRED CALCULATION INTERVAL LOSS RATElGREEN ANC AKPT INFILTRATIONKINEMATIC WAVE: NEW FINITE DIFFERENCE ALGORITHM HEC-l INPUT PAGE LINE 1z 3 4 5 6 T B 9 10 11 12 11 1* IS 16 17 18 19 20 ID.... ID 10 ID ID IT 10 KK KM IN PB PI PI PI BA LS UD 10 DRAINAGE STUCT FOR N£ QUACR&NT OF CARLSBAD FOR ULTIMATE CONDITIONS OF WATERSHED DEVELOPMENT 6-HOUR STORM, 100-YEAR EVENT ZCNES 7, 14 AND 15 5 75 5 CL Al RUNOFF FROM CALAVERA LAKE BASIN AI 15 2.90 ,0175 .0175 .0225 .05 .05 .04 0 .IBS .02 0.74 .02 90 .02 .02 0225 .04 .02 0.45 KK CL A2 KM RUNCFF FROM CALAVERA LAKE BASIN A2 BA 0.21 LS 90 .0275 .0275 .0275 .0275 .0475 .0225 .0475 .0225 0.165 .02 i I 21 UD 0.23 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 LIhE 46 47 48 49 SO 51 52 53 54 55 56 57 58 59 £0 61 62 63 64 €5 66 KK KM HC KK KH RS RC RX RT KK KM PB 6A LS UD KK KN HC KK KM PB BA LS UD KK KH HC KK KN RS RC RX RY KK KM PS 6A LS UD KK KM HC KK KM PB PT. 1 COMBINE 2 CL A3CHANNEL FLOUS CF fil AND 42 ROUTING THROUGH CALAVERA LAKE BASIN A3 1 STUB -1 0.022 0. 465 355 CL A3 fiUNCFF 2.85 0.48 0.25 PT. 2 COMBINE 2 CL A4 RUNOFF 2.90 0.68 0.49 PT. 2 COMBINE 2 CL ASCHANNEL 022 0.022 4200 0.012 475 465 495 5C5 SIS 525 535 350 345 340 3*3 3*5 350 355 FROM CALAVERA LAKE BASIN A3 89 FLOW OF A3 WITH ROUTED FLOW FROM CALAVERA LAKE BASIN A4 90 MEC-1 INPLT FLOWS CF BASINS A3 AND *4 ROUTING THROUGH CALAVERA LAKE BASIN AS 1 STOR -1 0.022 0. 465 275 CL AS RUNOFF 2.00 0.20 0.19 CL AS COMBINE 2 CL A6 RUNCFF 2.80 022 0.022 3200 0.01* 475 485 495 EC7 517 527 537 270 265 260 26D 265 270 275 FROM CALAVERA LAKE BASIN 15 87 FLOW OF A5 WITH ROUTED FLOW FROM CALAVERA LAKE BASIN *i PAGE 10 I I I 1 fc i I i I j i I ; t i t i I * i i I i fc 6768 (9 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 as 86 87 PACE HUE 88 89 90 91 92 93 9* 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 e* LS UD KK KM MC KK KM RS RC RX BY KK KM PB BA LS UD KK KM HC ID KK KM PB BA LS UD KK KM HC KK KM PB BA LS UD KK KM HC KK KK KQ RS SAsess 0.50 0.25 PT. 3 COMBINE 2 CL AT CHAtthEL 87 FLOWS CF BASINS A5 AND A6 ROUTING THROUGH CALAVERA LAKE BASIN A? 1 STQR -I 0.030 0. 450 245 CL A7 BUNCFF 2.80 0.20 0.21 CL A7 COMBINE 2 CL AS RUNCFF 2.80 0.29 0.26 PT. 4 COMBINE 2 CL »9 RUNCFF 2.75 0.31 0.18 CL A9 COMBINE 2 PT. 5 STORAGE 3 030 0.030 2700 0.010 465 460 495 £15 530 545 560 240 235 230 230 235 240 245 FROM CALAVERA LAKE BASIN A7 88 FLOW OF A7 WITH ROUTED FLOW MEC-1 INPUT FROM CALAVERA LAKE BASIN AS 88 FLOWS CF BASINS A7 <NO A8 FflQH CALAVERA LAKE BASIN A9 90 FLOWS OF BASINS A7. A6. AND A9 ROUTING IN CBLAVERA LAKE 2 1 ELEV 209.0 21 20B 216.5 24 27 30 33 35 38 39.5 41 43 210 212 214 216 217 218 219 220 221 150 2.64 1.5 t i I i I i t i i t 1 I I i I 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 LlfcE 13* 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 KK CL 110 KM CHAhNEL ROUTING THROUGH CALAVERA LAKE BASIN A10 RS 1 STOR -1 RC 0.03S 0. RX 450 RV 165 KK CL MO KM RUNOFF PB 2.70 BA 0.36 LS UO 0.19 KK PT. 6 KM COMBINE HC 2 KK CL All KM RUNCFF PB 2.75 BA 0.23 LS UD 0.21 KK PT. 6 KK COMBINE HC 2 KK CL *12 KM CHANNEL RK 3100 0. KK CL A1Z KM RUNCFF PB 2.70 BA 0.34 LS UO 0.23 KK PT. B KM COMBINE HC 2 KK CL LI KM RUNCFF PB 2.80 BA 0.49 LS UO 0.35 KK CL L2 KM RUNCFF P» 2.60 BA 0.43 LS 045 0.035 3600 0.027 465 490 495 515 530 545 560 160 155 150 150 155 160 165 FRON CALAVERA LAKE BASIN A10 87 FLOhS CF BASIN A10 hITH ROLTED FLOW FROM CALAVERA LAKE BASIN All 66 MEC-1 INPUT FLOWS OF BASINS A10 AND All ROUTING THROUGH CALAVERA LAKE BASIN A12 007 0.035 20 3 FROM CALAVERA LAKE BASIN A12 87 FLOtaS OF BASIN A12 WITH ROITED FLCW FROM CALAVERA LAKE BASIN LI 66 FROM CALAVERA LAKE BASIN L2 66 PAGE 10 iilititi!: ijtiiitiiJtltii 160 UO 0.27 161 KK PT. 7 162 KM COMBINE FLOWS CF BASINS LI AND L2 163 HC 2 1C* KK CL L3165 KM CHASNEL ROUTING THROUGH CALAVERA LAKE BASIN L3 166 US 1 STOR -1 167 RC 0.030 0.040 0.030 4700 0.036 168 RX 450 465 4BO 495 505 520 535 550 169 Rf 115 110 103 100 100 105 110 115 170 KK CL L3 171 KM RUNOFF FROM CALAVERA LAKE BASIN U3 172 PB 2.75 173 BA 0.39 174 LS 86 175 UD 0.30 HEC-l INPUT PAGE LINE ID 1 2 3 ..4 5 6 7 8 9 10 176 KK PT. 8 177 KN COMBINE FLOWS OF BASIN L3 WITH ROUTED FLOW 178 HC 2 179 KK PT. B 1BO KN COMBINE FLOWS CF BASIN A12 hITH ROUTED FLOW FROM L3 181 HC 2 182 KK CL A12 183 KN CHANNEL ROUTING THROUGH CALAVERA LAKE BASIN A12 184 RS 1 STOR -1 185 RC 0.030 0.028 0.030 1200 0.007 166 RX 4B2 488 494 500 506 512 516 524 187 RY 52 48 44 40 40 44 48 52 188 KK CL A13 189 KK CHANNEL ROUTING THROUGH CALAVERA LAKE BASIN A13 ISO RS 1 STOR -1 191 RC 0.030 0.028 0.030 2050 0.004 192 RX 492 488 494 500 506 512 518 524 193 RV 47 43 39 35 35 39 43 47 194 KK AQUAUA 195 KM RUNCrF FROM AOLA HEOIONCA BASIN UA 146 Pfl 3.2Q 197 BA 6.50 198 LS 91 19t UD 1.02 200 KK AQUAU9 201 KM RUNOFF FROM AQUA HEDIONO* BASIN UB 202 PB 3.IS 203 BA 3.00 204 LS 91 205 UD 0.76 i i t i i i i i t 2C6 207 208 209 210 211 212 213 214 215 216 217 218 219 220 LIhE 221 222 223 224 22S 226 227 228 229 230 231 232 233 23* 235 236 237 238 239 240 241 242 243 244 245 246 247 248 249 250 KK KB HC KK KM R5 RC RX RY KK KM PBa* LS UD KK KM HC KK KM PS BA LS UD KK KM PS BA LSuo KK KH *C KK KH RK KK KH PB BA LS UO KK KN HC PT 10 COHBIKE FLObS FROM AQUA BASINS UA ASO UB 2 AQLAUF ROUTING THROUGH CMSKEL IN BASIN JF 1 STOB -1 0.030 0.0*0 0.030 7300 0.0075 EOO 905 965 1000 1020 1040 1100 1315 350 325 320 318 319 320 325 350 AOLJAUF RUNCFF FROM &GUA n:CICNDA BASIN UF 2.95 1.11 89 0.46 MEC-1 INPLT AQUAUF COHEINE FLOWS FROM AQUA HEDIQNDA SASIN UF AM) RQUTEC FLOW 2 AQUAUE RUNOFF FROM AQUA HECIONOA BASIN UE 2.65 0.242 88 0.17 AQUAUG RUNOFF FROM ACUA HECIONCA BASIN UG 2.90 1.15 89 0.41 PT 11 COMBINE FLOWS FROM EASIMS UE, U?i AKO UG 3 ACUA G ROUTING THROUGH CHANEL IN EASIh G B200 0.022 0.033 0 0 20 3 AQUA G RUNCFF FROH AQUA HECIOKDA BASIN G 2.60 0.51 87 0.38 PT 12 COMBINE FLOW FOCH BASIN G WITH RCUTEC FLOW 2 PAGE 10 251 KK AQUAUC 252 253 25* 2S5 256 257 253 2S9 2£0 2(1 262 LIKE 2«3 2£4 2*5 2*6 267 268 269 270 271 272 273 274 27S 276 27727a 279 280 211 212 2!3 28* 285 286 287 218 269 2SO 2S1 2S2 2S3 29* 295 2S6 KM PB BA LS UD KK KN PB BA LS UD ID. KK KM HC KK KM R$ RK KK KH PB BA LS UD KK KM MC KK KN RK KK KM PB BA LS UD KK KM HC KK KM HC KK KM RK RUNOFF FROM AQUA HEDICNCA BASIN UC 3.00 1.65 90 0.60 AOUAUD RUNOFF FROM AQUA HEDIONCA EASIN LO 2.85 0.*2 68 0.22 MEC-1 INPUT PAGE PT 13 COMBINE FLOWS FROM UC AND UD 2 ACUA H ROUTING THROUGH CHANNEL IN BASZN H 10 STOR -1 0 2300 0.018 0.032 0 0 20 3 AQUA H RUNOFF FROM AQUA HEDIDNOA BASIN H 2.80 0.3S 88 0.20 PT 1* COMBINE FLOW FRCK BASIN H WITH ROUTEC FLCU 2 AOUA f ROUTING THROUGH CHANKEL IN BASIN F 4200. 0.022 0.033 0 0 20 3 AQUA F RUNOFF FROM AQUA MECIONOA BASIN F 2.80 0.96 91 0.17 PT 12 COMBINE FLOW FROM BASIN F WITH ROUTED FLDW 2 PT 12 COMBINE FLOW FROM BASIN G WITH RCUTED FLOW 2 AQUA C ROUTING THROUGH CHAhhEL IN BASIN E 4200 0.010 0.035 0 0 20 2 297 298 299 300 301 302 LIKE 303 304 305 306 307 308 309 310 311 312 313 314 315 316 317 318 319 320 321 322 323 324 325 326 327 328 329 330 331 332 333 3*4 335 336 337 338 339 340 3*1 KK KM PBe» LS UD ID. KK KH HC KK KM RK KK KH BA LS UD KK KH HC KK KH RK KK KM BA LS UO KK KM HC KK KM RK KK KM PB BA LS UO KK KM HC KK KM AQUA E RUNOFF FROM AQUA HECIQNDA BASIN E 2.75 0.58 86 0.23 HEC-1 INPUT FT 15 COMBINE FLOW FROM B*SIN E WITH ROUTED FLOW 2 AQUA 0 ROUTING THROUGH CHANNEL IN BASIN 0 1200 0.010 0.035 0 0 25 2 AQUA 0 RUNOFF FROM AQUA HEDIONDA BASIN D 0.28 06 0.16 PT 16 COMBINE FLOW FROM BASIN 0 WITH ROUTED FLOW 2 AQUA C ROUTING THROUGH CHANNEL IN BASIN C 600 0.010 0.032 25 1.5 AQUA C RUNOFF FROM AQUA HECIONOA BASIN C 0.302 90 0.12 PT 17 COMBINE PLOW FROM BASIN C WITH ROUTED FLOW 2 AQUA B ROUTING THROUGH CHANNEL IN BASIN B 3600 0.007 0.030 25 1.5 AQUA 9 RUNOFF FROM AQUA HEOIONOA BASIN B 2.70 0.25 87 0.2& PT 18 COMBINE FLOW FROM BASIN B WITH ROUTED FLOW 2 PT 18 COMBINE FLOWS FROM AQUA HECIONCA CREEK AND CALAVERA CREEK P6SE 8 10 342 LINE HC ID, HEC-1 INPUT PAGE 10 3*3 344 345 346 347 348 349 350 351 352 353 354 355 356 357 358 359 360 361 3(2 3*3 364 36S 366 367 368 369 KK CL A13 KM RUNOFF FROM CALAVERA LAKE BASIN A13 P9 2.70 64 0.17 LS 67 UO 0.15 KK PT 18 KH COMBINE FLOWS CF BASIN A13 WITH POUTED FLCU HC 2 KK AOUA14 KH RUNOFF FROM BASIN A14 PB 2.70 BA 0.43 LS 87 UO 0.18 KK PT 18 KH COMBINE FLOWS CF BASIN A14 fclTH ROUTED FLOW HC 2 KK AQUA A KM RUNOFF FROM AQUA HEDIONCA BISIN A BA 0.283 LS 86 UO 0.10 KX KM HC ZZ PT 19 COMBINE FLOWS CF BASINS A AND 6 2 144444*4****4*44444***44**4****444444***4* 4 * * FLOOD MTOROGRAPH PACKAGE (H£C-1> 4 * FEBRUARY 1981 * * REVISED 02 AUG 88 * 4 4 * RUN DATE 07/01/1989 TIME 11:22:44 4 * * 444****4444444444444*44**44**»***44444*44 44444***»*444444444*444444*4444**444444 4 * 4 U.S. ARMY CORPS OF ENGINEERS 4 4 THE HYDROLCGIC ENGINEERING CENTER * * 609 SECOND STREET 4 4 DAVIS, CALIFORNIA 95616 4 * (916) 551-17*8 * 4 * 4**»4«4444*44*44*444444*4«*44»4* 44*4*44 DRAINAGE STUDY FDR NE QUADRANT OF CARLSBAD FDR ULTIMATE CONDITIONS OF WATERSHED DEVELOPMENT 6-HOL'R STORM, 100-YEAR EVENT ZONES 7, 14 AND 15 6 10 OUTPUT CONTROL VARIABLES 1PRNT S PRINT CONTROL IPLOT 0 PLOT CONTHDL CSCAL 0. HYDRDGRAPH PLCT SCALE IT HYCROCRAPH TIME DATA NMIN 5 IOATE 1 0 ITIME 0000 NO 75 NCDATE 1 0 NCTIME C610 ICENT 19 COMPUTATION INTERVAL TOTAL TlPE BASE MINUTES IN COMPUTATION INTERVA STARTING C6TE STARTING TIME NUMBER OF MYDROGRAFH ENDING DATE ENDING TIME CENTURY MACK .08 HOURS 6.17 HOURS OROINATES ENGLISH UNITS DRAINAGE AREA PRECIPITATION DEPTH LENGTH. ELEVATION FLOW STORAGE VOLUME SURFACE AREA TEMPERATURE SQUARE MILES INCHES FEET CUBIC FEET PER SECOND ACRE-FEET ACRES DECREES FAHRENHEIT *** *** *** *** *** *** *** *** »** 4** *** »** *«* *** *** *** *** »** *** ****** *** *#* *** *** *** *** *** *** *** *** 106 KK 10B KO 109 RS 110 SA 111 SE 112 SS *************** * * PT. 3 * * *************** OUTPUT CONTROL VARIABLES IPRNT 3 PRINT CONTROL IPLQT 2 PLOT CONTROL CSCAL 0. HTDROGRAPH PLOT SCALE HYDROGRAPH ROUTING DATA STORAGE ROUTING NSTPS ITTP RSVR1C X AREA 1 NUMBER OF SUBREACHES ELEV TYPE OF INITIAL COhCITION 209.00 INITIAL CONDITION .00 WORKING R AND D COEFFICIENT 21.0 ELEVATION SPILLWAY CREL SPWID COQH EXPU 20B.OO 24.0 210.00 27.0 212.00 30.0 214.00 216.50 SPILLhAY CREST ELEVATION 150.00 SPILLWAY WIDTH 2.6* WEIR COEFFICIENT 1.50 EXPONENT CF HEAD 33.0 35.0 216.00 217.00 36.0 39.5 41.0 43.0 21S.OO 219.00 220.00 221.00 COMPUTED STCRAGE-ELEVATION STORAGE ELEVATION .00 208.00 44.97 210.00 95.94 152.91 215. E9 212.00 214.00 216.00 249.88 217.00 286.37 218.00 325.12 365.37 407.36 219.00 220.00 221.00 COMPUTED OUTFLCH-ELEVftTION CAT* *** OUTFLOW ELEVATION OUTFLOWELEVATION STORAGE OUTFLOW ELEVATION STORAGE OUTFLOW ELEVATION STORAGE OUTFLOW ELEVATION .00 208. CO 472.52 217. £3 .00 .00 208.00 244. £6 81.032i6.es .00 216.50 648.18 217.89 44.97 .00 210.00 249.88 140.01 217.00 325.12 333.93 1565.33 1778.62 219. GO 219.22 ****** .65 5.19 17.50 216.51 216.56 216.63 862.73 1120.06 1424.06 213.18 216.50 218.85 COMPUTED STORAGE-OUTFLOW- 95.94 152.91 215.89 .00 .00 .00 212.00 214.00 216.00 256.25 263.72 272.34 222.33 331.87 472.52 217.18 217.39 217. C3 350.10 365.37 367.65 2187.61 2592.97 2654.95 219.63 220.00 220. C6 41.49 216.72 1778.62 219.22 ELEVATION 232.63 .00 216. SO 282.17 648.18 217.89 386.70 3184. SI 22C.51 81.03 216.65 2187.61 219.63 DATA 233.11 .65 216.51 286.37 727.50 218.00 407.36 3780.19 221.00 140.01 222.33 331.87 217.00 217.18 217.39 2654.95 3194.51 3780.19 220.06 220.51 221.00 234.53 236.90 240.24 5.19 17.50 41.49 216.56 216.63 216.72 293.26 305.56 319.10 862.73 1120.06 1424.06 218.18 218.50 218.85 *** *t* KYDROGRAPH AT STATION PT. 5 PEAK FLOW CCFS) 477. TIME CHR> 6.08 CCFS> (INCHES) CAC-FTJ PEAK STORAGE TIME CAC-FT) (HR> 273. 6.08 PEAK STAGE TIME <F£ET> CMR) 217,63 «.08 CUMULATIVE 6-HR 131. .338 65. 6-H3 139. 6-HR 213.14 AREA > MAXIMUM AVERAGE FLOW 24-HR 72-HR 128. 128. .338 .338 65. 65. MAXIMUM AVERAGE STORAGE 24-HR 72-HR 136. 136. MAXIMUM AVERAGE STAGE 24-HR 72-HR 213.02 213.02 3.61 SQ MI 6. 17-HR 128. .338 65. 6.17-t-R 136. 6.17-HR 213.02 STATION PT. 5 0 0 too. 0. CD INFLOW, CO) 800. 1200. 0. 0. OUTFLOW 1600. 2000. 2400 0. 0. 0 0 100 0. CS> STORAGE 200. 0. 0. 0 300. 0. 0 0. 0. OAHRHN i ft ft ft ni v v v y 10005 10010 10015 10020 10025 10030 10035 10040 10045 10050 10055 10100 10105 10110 10115 10120 10125 10130 10135 10140 10145 10150 10155 10200 10205 10210 10215 10220 10225 10230 10235 10240 10245 10250 10255 10300 10305 10310 10315 10320 1032S 10330 10335 10340 10345 10350 1C355 10400 10405 10410 10415 10420 10425 10430 10435 104*0 10445 10450 PER 21 ..... 31 ..... 41 ..... 51 ..... 61 * .... TI ..... SI ..... 91 ..... 101 ..... 121 ..... 131 ..... 141 ..... 151 ..... 161 ..... 171 ..... 181 ..... 191 ..... 201 ..... 221 ..... 2301 ..... 2401 ..... 250 X . . . . . 260 X 270 I 280 I . . 290 I . 300 .1 .... 320 . I 330 . . I 340 . . . I 350 360 ..... 370 ..... 360 ..... 390 . . . . .1 400 . . . . I . 420 I. 430 . . I 440 . . . I . 450 . . .1 460 . .1. . 470 . . I . 480 . . I . 490 . X 500 . . X . 52. 0 I 53. 0 I. 54. 0 I . 55. 0 . I . 56. O.I. 57. O.I. 58. D. I . 59. 01. . S . S .. s. s . s. s. s. s. s . s. s .. s. s. s. s .. s. s. s . s .. s. s . .5. s. s. s. s. s ss .s . I . S . I. S. .... I . S I . S. s ss....s . 5 .s.s.s. s. s. s .s . sssssss .s . . . . * . . , m 4 . u , 4 . f 4 . , 4 . . . . . . * • * * . * * , * . . 4 4 . . . . . . . 4 . . . . . 4 . i I 1 i 11 * * * * + * * * * * * 10455 10500 10505 10510 10515 10520 10525 10530 10535 10540 10545 10550 10555 10600 10605 10610 60. 01. 62. .0 I 63. .0 I 64. . 01 65. . 0! 66. .1 67. .1 63. .1 69. .1 70. .1 72. .1 73. .1 74. .1T e. _________ _T— — — OPERATION STATION HYOROGRAPH AT CL Al HYOROGRAPH AT CL A2 2 COMBINED AT PT. 1 ROUTED TO CL A3 HYDROGRApH AT CL A3 2 CCMBINED AT PT. 2 HYDROGRAPH AT CL A4 2 COMBINED AT PT. 2 ROUTED TO CL A5 S . S .s .s .s .s .s .. . . . . .s. .s .s . s .s .s . RUNOFF SUMMARY FLOW IN CI-6IC FEET PER SECCND TIME IN HOURS* AREA IN SQUARE MILES PEAK TIME OF AVERAGE FLCU FOR MAXIMUM PERIOD BASIN KAXIMUM TIME OF FLOW PEAK AREA STAGE MAX STAGE 6-HDUR 24-HOUR 72-HOUR 524. 3.00 141. 137. 137. .74 194. 2. 83 41. 40. 40. .21 674. 3.00 182. 177. 177. .95 660. 3.00 179. 174. 174. .95 343.22 3.00 399. 2.83 88. 85. 35. .4B 1004. 2.92 266. 259. 259. 1.43 463. 3.08 128. 125. 125. .68 1445. 3.00 395. 384. 334. 2.11 1433. 3.00 390. 3BO. 3SO. 2.11 264.30 3.00 HYDROGRAPH AT 2 COMBINED AT CL AS CL AS 158. 2.83 1539. 3.00 33. 423. 32. 412. 32. 412. .20 2.31 t 1 HYDROGRAPH AT 2 COMBINED AT ROUTED TO HYDROGRAPH AT 2 CCM6INED AT HYDROGRAPH AT 2 CCMBINEO AT HYDRDGRAPH AT 2 CCMBINEO AT ROUTED TO CL PT. CL CL CL CL PT. CL CL PT. A6 3 AT AT AT AS * A9 A9 5 363. 1650. 18*7. 163. 1966. 219. 2155. 277. 23*7. *77. 2.83 2.92 3.00 2.83 3.00 2.83 3.00 2.83 2.92 6.08 81. 50*. 497. 3*. 531. 49. 580. 57. 637. 131. 79. 490. 48*. 33. 517. *8. 56*. 55. 620. 128. 79. 490. 4Bt, 33. 517. 4B. 56*. 55. £20. 128. .50 2.81 2.81 .ZO 3.01 .29 3.30 .31 3. 61 3.61 234.83 3.00 217.63 6.08 ROUTED TO CL A10 *77. 6.17 121.118.118,3.61 152.23 6.17 HYDROCRAPH AT 2 COMBINED »T HYCROGRAPH AT Z CCHBINEO AT ROUTED TO HYDROGRAPH AT 2 COMBINED AT HYDKOGRAPH AT CL A10 PT. 6 CL All PT. 6 CL A12 CL A12 PT. 8 CL LI 26S. 520. 163. 5*8. 5*7. 2*1. 655. 295. 2.83 6.17 2.83 6.17 6.17 2.83 2.92 2.92 ss. 177. 35. 211. 199. 52. 251. 7*. 5*. 172. 3*. 205. 193. 51. 2**. 72. 5*. 172. 3*. 205. 193. 51. 2**. 72. .36 3.97 .23 *.20 *.20 .34 4.5* .49 J i HTDROGKAPH AT Z COMBINED AT ROUTED TO HYOflOGfiAPH AT 2 COMBINED AT 2 COMBINED AT ROUTED TO CL 12 PT. 7 CL L3 CL 13 PT. 8 PT. 8 CL A12 319. 614. 582. 244. 811. 1455. 1439. 2.92 2.92 3.00 2.92 3.00 2.92 2.92 ROUTED TO HTOROGRAPH AT HYOROCRAPH AT 2 COMBINED AT ROUTED TO HYDROGRAPH AT 2 COMBINED AT HTOROGRAPH AT KYDROGRAPH AT 3 COMBINED AT ROUTED TO HYDROGRAPH AT CL A13 AQliAUA AOL'AUB PT 10 AQUAUF AOUAUF AQUAUF AQUAUG PT 11 AQUA G 1*29. 3.00 3545. 3.67 1896. 3.42 5299. 5132. 756. 5522. 209. 812. 5962. 3.58 3.75 3.08 3.75 2.B3 3.00 7.67 5961. 3.75 74, 148. 144. 58. 202. 453. 448. MO, 1336. 63«. 1972. 1880. 206. 2G86. 43. 210, 2338. 2285, 72. 144, 140. 56, 196. 440. 436. 428. 1300. 619. 1919, 1829, 200, 2029. 41. 204. 2275, 2223. 72. 144. 140. 56. 196. 440. 436. 428. 1300. 619. 1919. 1829. 200. 2029. 41, 204. 2275. 2223. .46 .97 .97 .39 1.36 5.90 5.90 5.90 6.50 3.00 9.50 9.50 1.11 10.61 ,24 1.15 12.00 12.00 102.85 47.10 43.01 324.05 3.00 2.92 3.00 3.75 2 COMBINED AT HYDROGRAPH AT HTORDGRAPH AT 2 COMBINED AT ROUTED TO HYDROGRAPH AT 2 COMBINED AT ROUTED TO HTDROGRAPH AT 2 COMBINED AT 2 COMBINED AT ROUTED TO HYDROGRAPH AT 2 COMBINED AT ROUTED TO HTOROGRAPH AT 2 COMBINED AT ROUTED TO HtOROGKAPH AT 2 COMBINED AT AQUA G PT 12 AQUAUC AOL'AUD PT 13 AQUA H AQUA H PT 14 AQUA F AQUA F PT 12 PT 12 A OLA E AQUA E PT 15 AQtA 0 AQLA 0 PT 16 AQUA C AQtA C 315. 6103. 1059. 346. 1231. 1231. 288. 1382. 13BO. 93*. 20*7. 7354. T342. 400. 7476. 7471. 308. 7533. 7531. 293. 3.00 3.T5 3.17 2.B3 3.17 3.17 2.83 3.00 3.08 2.75 2.83 3.67 3.67 2.83 3.67 3.67 2.83 3.67 3.75 2.75 81. 2365. 321. 73. 394. 391. 60. 451. 4*3. 190. 633. 2S9B. 2959. 87. 30*6. 3C3S. 42. 3080. 3076. 56. 78. 2301. 312. 71. 384. 380. 58. 439. 431. 185. 616. 2917. 2879. 85. 2964. 2955. 41. 2997. 2993. 54. 78. 2301. 312. 71. 384. 380. 58. 439. 431. 185. 616. 2917. 2879. 85. 2964. 2S55. 41. 2997. 2S93. 54. .51 12.51 1.65 .42 2.07 2.07 .35 2.42 2.42 .96 3.38 15.89 15.89 .58 16.47 16.47 .28 16.75 16.75 .30 a I ROUTED TO HYDROGRAPH AT 2 COMBINED AT 2 COMBINED AT PT 17 AQUA B AQUA B PT 18 PT 18 PT 19 7605. 3.75 7605. 3.75 174. 2.83 7663. 3.75 BZ76. 3.67 HYOROGRAPH AT CL A13 2 COMBINED AT PT 18 HTOROGRAPH AT AQUA14 2 COMBINED AT PT IB HYOHOGRAPH AT AQUA A 2 COMBINED AT 132. 2. 75 8313. 3.67 323. 2.83 8*10. 3.67 226. 2.75 8*71. 3.67 3132. 3095. 38. 313*. 3573. 26. 3600, 66. 3(66. 42. 3708. 30*8. 3012. 37. 3049. 3477. 26. 3503. 65. 3567, 41. 3608. 3C48. 3012. 37. 3C49. 3477. 26. 3503. 65. 3S67. 3608. 17.05 17.05 .25 17.30 23. 20 .17 23.37 .43 23. 80 ,28 24.09 ISTIO ELEMENT CL A12 DT SUMMARY OF KINEMATIC HAVE ROUTING(FLOW IS DIRECT RLNCFF WITHOUT BASE FLOW)INTERPOLATED TO COMPUTATION INTERVAL PEAK TIME TO VOLUME DT PEAK TIME TO PEAK PEAK (MIN) (CFS) (MIN) (IN) CHIN) CCFS> (MIN) .42 5*7.40 370.42 .4* 5.00 547.38 370.00 CONTINUITY SUMMARY (AC-FT) - INFLOW" 104.718 EXCESS',000 OUTFLOW- 98.880 BASIN STORAGE- VOLUME (IN) .4* 6.074 PERCENT ERROR* -.226 AQUA G 3 .36 5961.82 22*.*6 1.77 5.00 5960.85 225.00 1.77 CONTINUITY SUMMARY (AC-FT) - INFLOW- 1159.392 EXCESS- .000 OUTFLOW- 1133.80* BASIN STORAGE" 25.949 PERCENT ERROR* -.031 AQUA H 3 .56 1231.11 191.54 1.76 5.00 1230.57 140.00 1.76 CONTINUITY SUMMARY (AC-FT> - INFLOW- 195.606 EXCESS- .000 OUTFLCU= 194.176 BASIN STORAGE- 1.539 PERCENT ERRCB= -.056 AQUA F 3 .65 1381.16 183.74 1.71 5.00 1379.89 185.00 1.70 CONTINUITY SUMMARY (AC-FT) - INFLOW- 223.558 sXCESS- ,OCO CUTFLCW- 220.277 8ASIN STORAGE- 3.364 PERCENT ERRCR- -.037 AQUA E 3 .34 7353.86 Z22.39 1.73 5.00 7341.56 220.00 1.73 CONTINUITY SUMMARY <AC-FT) - INFLOW= 1486.810 EXCESS- .000 CtTFLCW- 1468.786 BflSIN STORAGE* 18.459 PERCENT :RRCR« -.029 •QUAD 3 .26 7476.20 220.61 1.72 5.00 7*70.95 220.00 1.71 CONTINUITY SUMMARY (AC-FT> - INFLOW* 1510.390 EXCESS- .000 CUTFLCH» 1506.904 BASIN STOR«GE« 3.992 PERCENT ESBCR- -.033 »OUA C 3 .12 7533.03 ?20.26 1.71 5.00 7530.97 225.CO 1.71 CONTINUITY SUMMARY CAC-FT) - INFLOW- 1527.262 EXCESS* .000 CUTFLCW- 1525.643 BASIN STORAGE" 1.835 PERCENT ERRCR- -.015 AQUA B 3 .34 7605.44 226.71 1.69 S.OO 7605.24 225.00 1.69 CONTINUITY SUMMARY CAC-FT) - INFLOW' 1553.156 EXCESS" .000 CUTFLCW. 1536.158 3ASIN STORAGE- 17.163 PERCENT :RBCR= -.011 *** NORMAL END Of HEC-1 *** *************************«**t************************* * HATER SURFACE PROFILES * * VERSION OF NOVEMBER 1976 * » UPDATED HAY 198* * * * * RUN DATE 1-JUL-B9 TIKE 20:45:48 * **************************«$$****»******************** ************»***********»**4****4****»ft * U.S. ARNT CORPS OF ENGINEERS * * THE HTDROLOCIC ENGINEERING CENTER « * 609 SECOND STREET, SUITE 0 * * DAVIS* CALIFORNIA 95616 * * <916> 440-2105 (FTS) 4*8-2105 * ******3*******»*»*e«***********«4****** X X XXXXXXX XXXXX XXXXX XXX XX XX X X X X X XXXXXXX XXXX X XXXXX XXXXX X X X X X XXX XX X X X XXXXXXX XXXXX XXXXXXX l-JUL-89 PAGE A***********************#»**»*#****«**************HEC2 RELEASE DATED NOV 76 UPDATED MAY 198* ERROR CORK - 01 ,02,03,04,0«,06 HQDIFlCATia*, - SO,51,E2,53»54,55****************»**»4***********aa*aa********$**4* TV-IS RUN EXECUTED l-JUL-89 20!45:*.9 C Tl CALAVERA LAKE CREEK T2 ZOhE T AND 1CNE 14 T3 HOWARD H. CHAUG, JUNE 1989 Jl J2 CT HC ICHCCK 0. NPRCF -1.000 2.000 0.0*0 INQ KINV IDIR 2.0. 0. IPLOT PRFVS XSECV 0.000 -1 9850.000 0.040 DObNSTREAH FACE XI X3 6R GR SB 20.000 0.000 44.000 31.000 1.050 8.000 0.000 200.000 335.000 1.800 UPSTREAM FACE OF XI X2 XI X3 GR GR CT XI X3 GR GR GR XI K3 GR GR GR GR 20.100 0.000 21.000 0.000 40.000 32.000 2.000 22.000 0.000 43.000 31.000 44.000 23.000 0.000 44.000 32.000 44.000 43.900 0.000 0.000 9.000 0.000 235.000 309.000 8080.000 11.000 0.000 100.000 153.000 417.000 16.000 0.000 100.000 235.000 430.000 763.000 STHT •1.000000 XSECM .000 0.000 0.000 9850.000 0.030 OF EL CAMINO 250. OCO 0.000 38.000 36.000 3.000 0.000 0.200 REAL 350.000 220.000 250.000 350.000 150.000 METRIC 0.00 FN 0.000 0.000 0.4QO 0.000 0.000 31.000 44.000 70.000 HVINS 0.0 ALLOC 0.000 0.000 0.000 0.000 370.000 265.000 400.000 4.000 EL CAPIMQ REAL 0.000 1.000 260.000 0.000 40.000 34.000 8080.000 116.000 0.000 42.000 32.000 0.000 2C5.0CO 0.000 44.000 34.000 44.600o.oco 0.000 42.600 336.000 260.000 260.000 324.000 0.000 IBS. 000 116.000 116.000 159.000 0.000 288.000 198.000 198.000 270.000 605.000 0.000 110.000 44.000 190.000 0.000 34.000 40.000 0.000 230.000 0.000 36.000 34.000 0.000 125.000 0.000 42.000 42.000 45.000 0.000 110.000 O.OCO 160.000 360.000 275.000 336.000 O.OCO 190.000 220.000 130.000 185.000 0.000 113. OCO 430.000 205.000 288.000 705.000 0.000 0 WSEL FQ 0. 40.500 0.000 IBW CHMH ITRACE 0.000 0.000 0.000 0.000 0.000 0.000 0.000 29.500 0.000 1020.000 110.000 0.000 170.000 0.000 32.000 42.000 0.000 215.000 0.000 34.000 42.000 0.000 121.000 0.000 32.000 44.000 49.000 0.000 0.000 0.000 0.000 0.000 300.000 0.000 2.000 0.000 0.000 0.000 O.OCO 292.000 360.000 0.000 0.000 0.000 137.000 202.000 0.000 0.000 0.000 228.000 310.000 705.500 0.000 0.000 0.000 0.000 0.000 30.000 0.000 29.500 0.000 0.000 -2.500 0.000 31.500 0.000 0.000 0.000 0.000 32.000 42.700 0.000 0.000 0.000 31.500 43.600 45.000 0.000 O.OCO 0.000 0.000 O.OCO 315.000 0.000 29.500 0.000 0.000 0.000 O.OCO 300.OCO 0.000 0.000 0.000 O.OCO 148.000 235.000 0.000 O.OCO 0.000 232.000 393.000 706.000 O.OCO l-JUL-89 20145:49 PAGE XI X3 GR OR GR CR XI X3 Cfi GR GR GR XI X3 GR GR GR GR XI 13 GR GR GR GR XI X3 GR GR GR GR XI X3 GR GR GR GR XI X3 GR GR GR GR 24.000 0.000 44.000 34.000 44.000 44.403 25.000 O.OCO 46.000 33.400 45.000 44. SCO 26.000 0.000 46.000 38.000 46.000 47.000 27.000 0.000 48.000 45.300 38.000 49.400 28.000 0.000 49.400 46.000 48.000 50.000 29.000 0.000 SO. 000 46.600 36.000 52.000 30.000 0.000 50.000 48.000 39.000 52.500 16.000 0.000 100.000 347.000 575.000 900.000 16.000 0.000 100.000 463.000 673.000 1015.000 17.000 0.000 100.000 554.003 700.000 1056.000 20.000 0.000 100.000 SB*. 000 685.000 1093.000 17.000 0.000 100.000 825.000 928.000 1318.000 19.000 0.000 100.000 848.000 945.000 1351.000 20.000 0.000 100.000 961.000 1053.000 1493.000 308.000 0.000 44.700 26.000 45.000 0.000 423.000 O.OCO 46.000 34.000 45.200 0.000 5*2.000 0.000 47.600 36.000 48.000 46.400 615.000 0.000 49.3CO 44.000 46.0CO 48.000 825.000 0.000 49.500 40.000 49.100 50.000 870. OCO 0.000 50. OCO 46.000 40.000 56.000 975.000 0.000 50.000 46.000 40.000 54.000 393.000 300.000 235.000 375.000 722.000 0.000 SOB. 000 300.000 300.000 468.000 SS4.000 0.000 625.000 440.000 205.000 563.000 769.000 1118.000 705.000 580.000 202.000 615.000 705.000 1118.000 928. OCO 750.000 243.000 838.000 1035.000 1380.000 970.000 800.000 223.000 870.000 955.000 1351.500 1078.000 900.000 390.000 975.000 1062.000 1528.000 145.000 0.000 44.000 42.000 45.500 0.000 165.000 0.000 44.000 36.000 45.300 0.000 305.000 0.000 46.800 35.500 46.600 O.OCO 245.000 0.000 49.000 40.000 47.200 52.000 254.000 0.000 49.400 38. 000 50.000 0.000 262.000 0.000 48.000 40.000 48.000 52.000 150.000 0.000 4B.OOO 40.000 46.000 56.000 120. OCO 450. OCO 308. OCO 393.000 837.000 0.000 145. CCO 500.000 423.000 485.000 955. OCO 0.000 302.000 650.000 440.000 593.000 653. OCO 0.000 245.000 750.000 322.000 622.000 735.000 1118.500 254.000 950. OCO 518.000 847.000 1203.000 O.OCO 266.000 1000.000 508. OCO 883. 000 970. OCO 1352. OCO 185.000 1100.000 597.000 988. OCO 1078.000 1528. 500 137.000 0.000 34.000 44.000 49.500 0.000 157.000 0.000 36.000 42.000 49.800 0.000 305.000 0.000 46.000 36.000 47.000 0.000 245.000 0.000 46.000 38.000 48.800 48.000 254.000 0.000 48.000 37.000 50.000 0.000 264.000 0.000 48.000 36.000 50.000 52.000 168.000 0.000 47.500 39.000 50.000 54.000 0.000 0.000 332.000 428. OCO 837.500 0.000 0.000 0.000 439.000 508.000 955.500 0.000 O.OCO 0.000 535.000 602.000 1055.000 0.000 0.000 0.000 402.000 632.000 856. OCO 1119.000 0.000 0.000 702.000 674.000 1317.000 0.000 O.OCO 0.000 665.000 890.000 1023.000 1412. OCO O.OOC 0.000 765.000 994.000 1120.000 1529. OCO 0.000 0.000 32.300 44.700 45.500 O.OCO 0.000 0.000 34.000 44.000 45.800 0.000 0.000 0.000 44.000 44.000 51.000 0.000 0.000 0.000 46.000 36.000 48.000 4B.OOO 0.000 0.000 46.000 38.000 54.000 0.000 0.000 0.000 48.000 37.600 51.300 0.000 0.000 0.000 47.100 38.300 52.000 54.600 o.occo.occ 340. OCC 485. CCC 839. OCCo.oc: O.OCOo.occ 459. CCC 515.000 956. OCO 0.000 0.000 0.000 542. OCO 625. OOC 1055.500 O.OOC O.OCO 0.000 537. CCC 643.000 897. OCC 1184.000 0.000 O.OOC 788. OCC 696. OCC 1317. SCO 0.000 O.OCCo.ccc 762. OCC 917.000 1250. CCC O.OCO 0.000 O.OCO 885.000 1024. OCO 1255.000 1598. OCO i i l-JUL-89 20:45:49 PAGE XI X3 GR GR CR GR XI X3 GR GR CR GR GR XI X3 GR CR GR CR GR XI X3 GR GR GR GR GR GR GR XI X3 GR GR GR GR &R XI X3 GR GR GR GR GR 31. OCO 0.000 50.000 48.000 50.000 60.000 32.000 0.000 52.000 56.000 50.000 *2.000 56.000 33.000 0.000 52.000 52.000 40.000 56.000 60.000 34.000 0.000 55.300 56.000 54.000 56.000 46.000 57.000 58.000 35.000 0.000 54.700 56.000 43.000 58.000 58.000 36.000 0.000 58.300 58.000 43.900 58.000 61.000 IB. 000 0.000 100.000 985.000 1120.000 1651.500 25.000 0.000 100.000 910.000 1255.000 1343.000 1932.000 25.000 0.000 100.000 1082.000 1221.000 1352.000 192*. SOO 31.000 0.000 100.000 378.000 1042.000 1258.000 1329.000 1753.000 3063.000 25.000 0.000 100.000 1180.000 1295.000 1404.000 2008.000 24.000 0.000 100.000 1213.000 1282.000 1352.000 1985.000 1015.000 0.000 49.700 46.000 S2.000 £6.000 1255.000 0.000 52.000 57.500 42.000 54.000 56.000 1199.000 0.000 52.000 52.000 39.9CO 57.200 56.000 1258.000 0.000 54.000 54.0CO 56.000 46.000 56.000 56.000 O.OCO J2S1. 000 0.000 56.000 58.000 44.000 59.000 60.000 1235.000 0.000 60.0GO 56.000 44.000 58.000 £5.000 1120.000 950.000 395.000 1015.000 1244.000 1652.000 1378.000 1180.000 515.000 990.000 1273.000 1378.000 1993. OCO 12BO.OOO 1180.000 384.000 1180.000 1227.000 1453.000 1929.000 1345.000 1250.000 210. OCO 382.000 1078.000 1279.000 1345.000 1951. OCO 0.000 1343.000 1251.000 255.000 1207.000 1302.000 14E5.00C 2016.000 1333.000 1235.000 285.000 1235.000 1265.000 1608.000 1985.500 127.000 0.000 49.000 40.000 54.600 56.500 265.000 0.003 50.000 56.000 40.000 55.400 60.000 52.000 0.000 50.400 50.000 40.000 56.000 60.000 135.000 0.000 53.300 54.000 56.000 44.000 SB. 000 SB. 000 0.000 91.000 0.000 56.000 SB. OCO 46.000 57.700 64.000 121.000 0.000 59.100 43.000 46.000 56.800 61.000 137. OCO 11SO.CCO 497.000 1025. OCO 1386. OCO 1730.000 253.000 1380. OCO 757. OCO 1088. OCO 1282.000 1443. OCO 1993.500 48. OCO 1350.000 638.000 1199. OCO 1232.000 1650. CCO 1929.500 125.000 1420.000 275.000 687. OCO 1178.000 1288. OCO 1420. OCO 2018.000o.occ 88.000 1400.000 415.000 1251.000 1324.000 1575. OCO 2016. SCO 107. OCO 1350.000 608.000 1255.000 1305.000 1655.000 1966.000 130.000 0.000 48.000 28.700 '4.000 0.000 260.000 0.000 52.000 50.000 39.800 56.000 56.000 45.000 0.000 54.000 44.000 42.000 56.000 56.000 130.000 0.000 54.000 52.300 58.000 42.500 58.000 62.000 0.000 BB.ooo 0.000 56.000 46.000 54. OCO 56.000 60.000 114.000 0.000 58.000 46.000 48.000 SB. 000 £0.500 O.OCO O.DCO 613.000 1060. OCO 1465.000 O.OCO 0.000 0.000 815.000 1190.000 1303.000 1491.000 1994.000 0.000 0.000 747.000 1212. OCO 1246.000 1867.000 1930.000 0.000 0.000 305.000 838.000 1219. OCO 1300.000 1495.000 2018.500 0.000 0.000 0.000 575. OCO 1278. OCO 1343.000 1855. OCO 2017.000 0.000 0.000 732. OCO 1262.000 1315.000 1630.000 2065. OCO 0.000 0.000 48.000 40.000 56.000 0.000 0.000 0.000 54.000 50.000 40.000 56.000 52.400 0.000 0.000 56.000 42.000 54.000 56.000 57.600 0.000 0.000 54.000 54.000 58.000 44.000 57.000 58.000 0.000 0.000 0.000 S6.000 44.000 56.000 55.200 59.000 0.000 0.000 58.000 44.000 56.000 60.000 0.000 0.000 0.000 870.000 1097. OCO 1651.000 0.000 0.000 0.000 B44.000 1202.000 1315.000 1610.000 2055.000 0.000 0.000 800.000 1219.000 1280.000 1928.000 1988.000 0.000 0.000 310.000 890.000 1Z36.000 1320.000 1589.000 2019.000 0.000 0.000 O.OCO 654.000 1288.000 1361.000 196S.CCO 2090.000 0.000 0.000 922.000 1275.000 1333.000 1945.000 0.000 l-JUL-89 20:45:49 PftGE XI X3 GR GR GR GR GR GR SB ET XI X2 X3 BT BT BT ST BT BT BT BT BT NC ET CT XI Gfi GR GR ET XI GR GR GR ET XI GR GR GR ClT NC XI GR 37.000 0.003 70.000 60.000 46.000 44.500 •-4.500 61.000 1.200 0.000 39.000 0.000 0.000 -26.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.035 0.000 2.000 39.000 70.000 58.800 48.000 0.000 40.000 70.000 58.600 56.000 0.000 41.000 70.000 59.000 58.000 2.000 0.040 -21.000 43.000 26.000 0.000 100.000 1002.000 1*44.100 1*69.000 1482.100 2258.000 1.250 0.000 0.000 0.000 0.000 100.000 639.000 1278.000 1444.000 1454.100 1469.000 1469.900 1503.000 1730.000 0.035 8.100aooo.ooo 15.000 100.000 1198.000 1434.000 8.100 15.000 100.000 1168.000 1388.000 8.100 14.000 100.000 1174.000 1348.000 1740.000 0.040 5.000 480.000 1423.000 0.000 £0.000 40.000 46.000 44. SCO £6.000 0.000 3.0CO 6.100 0.000 1.000 O.OCO 70.000 (0.000 CO. 000 58.000 58.000 58.000 58.000 58.0CO (0.000 0.030 6.100 8000.000 1377. 000 60.000 58.0CO 56.000 6. ICO 1335.000 60.0CO 58.000 S8.0CO 6.100 1295. OCO 60.000 58.000 56. COO 1740. OGO 0.030 480.000 32.000 1503.000 1300.000 215.000 1278.000 1456.000 1469.100 1503.000 0.000 0.000 0.000 0.000 56.000 1400.000 0.000 0.000 0.000 46.000 46.000 56.000 56.000 56.000 0.000 0.000 8.100 0.000 1447.000 220.000 1327.000 14*7.000 8.100 1388.000 166.000 1335.000 1408.000 6.100 1348.000 180.000 1295.000 1370.000 0.000 0.100 520.000 496.500 96.000 0.000 SB. 000 59.000 46.000 44.500 5 8. COO 0.000 39.000 0.000 46.000 58.000 0.000 215.000 742.000 1379.000 1444.100 1456.900 1469.100 1482.000 1556.000 2258.000 0.000 0.000 0.000 61.000 57.800 56.000 56.000 0.000 69.000 58.000 48.000 56.000 0.000 112.000 58.000 50.000 60.000 0.000 0.300 200.000 32.000 35. OCO uzo.oto 330.000 1279. OCO 1-.J6.1CO 1*49.800 1558.000o.ooo 1.7CO 1350.000 46.000 O.OCO IJOO.OOOto. oco 60.000 58.000 56.000 58.000 £8.000 58. OCO SB. OCO 61.000 0.000 1215.000 O.OCO 68. OCO 325.000 1377.000 1617.000 lliO.OCO 97.000 ICO. 000 1355.000 1557.000 1100.000 125.000 208.000 1303.000ms.oco O.OQC 0.000 200.000 500. OCO SO. 000 O.OCO £0.000 56.000 44.500 44. SCO 58.800 O.OCO 396.000 1600.000 46.00C 0.000 0.000 0.000 0.000 0.000 56.000 44.500 44.500 56.000 0.000 0.000 0.000 1 SCO. 000 0.000 62.000 60.000 48. OCO 60.000 1460.000 78.000 56.600 47.000 60.000 1415.000 120.000 56.600 48.200 75.000 0.000 0.000 200.000 32.000 0.000 0.000 639. OCO 1423.000 1456. 90C 1469. 9CO 1612.000 0.000 0.000 0.000 0.000 0.000 0.000 330.000 1002.000 1423.000 1456.000 1457.000 1469.600 1*82.100 1612.000 0.000 0.000 0.000 0.000 0.000 508.000 1395.000 1987.000 1050.000 0.000 325.000 1365.000 1897.000 540.000 0.000 335. OCO 1322.000 1S50.0CO 0.000 O.OCO 1.000 503.500 0.000 0.000 60.000 46.000 44.500 44.500 60.000 0.000 44.500 0.000 0.000 0.000 0.000 58.000 60.000 58.000 58.000 56.000 58.000 56.000 58.000 0.000 0.000 1670.000 0.000 0.000 60.000 46.200 75.000 1670.000 0.000 58.000 48.000 75.000 1700.000 0.000 56.000 50.000 0.000 0.000 0.000 0.000 43.000 0.000 O.OCO 742.000 1444.000 1457.000 1482. CCO 1730.000o.coo 44.500 0.000 0.000 O.OGO 0.000 0.000 0.000 56.000 56.000 56. OCO 44.500 44.500 0.000 0.000 0.000 0.000 0.000 0.000 830.000 1414.000 2015.000 0.000 0.000 624.000 1375.000 1932.000 O.OCO O.OCO 590.000 1335.000 O.OCO 0.000 0.000 0.000 520.000 l-JUL-89 20145149 P4GE XI GR XI GR XI GR XI GR XI GR XI GR XI GR XI GR XI GR XI GR XI GR XI GR XI GR XI GR XI GR XI GR EJ 1.000 43.800 2.000 44.600 3.000 45.400 4.000 46.200 5.000 47.000 6.000 4T.800 7.000 48.600 8.000 49.400 9.000 SO. 200 10.000 51.000 11.000 52.300 12.000 53.700 13.000 55.000 14.000 56.400 15.000 57.700 16.000 59.100 0.000 5.000 480.000 S.OOO 460.000 5.000 480.000 5.000 480.000 5.000 480.000 5.000 480.000 5.000 480.000 5.000 480.000 5.000 480.000 5.000 480.000 5.000 480.000 5.000 480.000 S.OOO 480.000 5.000 480.000 5.000 480.000 5.000 480.000 0.000 480. CCO 32.800 480. CCO 33.600 480. OCO 34.4CO 460.000 35.2CO 460. 000 36. CCO 480.000 36.500 480. OCO 37.600 480.000 38.400 480.000 39.200 480.000 40.0CO 480.000 *1. SCO 480. OCO 42.700 480.000 44. COO 480. OCO 45.400 480. 000 46.100 480.000 48.100 O.OCO 520.000 496.500 520.000 496.503 520.000 496. 500 520.000 496.500 520.000 496.500 520.000 496. 500 520.000 496.500 S20.000 496.500 520.000 496.500 520.000 496.500 520.000 496.500 520.000 496.500 520.000 496.500 520.000 496.500 520.000 496.500 520.000 496.500 0.000 200.000 32. 800 200.000 33.600 200.000 34.400 200.000 35.200 200.000 36.000 200.000 36.800 200.000 37.600 200.000 38.400 200.000 39.200 200.000 40.000 200.000 41.300 200.000 42.700 200.000 44.000 200.000 45.400 200.000 46.700 200.000 48.100 0.000 200. OCO 500. COO 200.000 500. OCO 200.000 500. OCO 200.000 500.000 200.000 500.000 200. OCO 500.000 200.000 500.000 200. OCO 500.000 200.000 500.000 200. OCO 500.000 200.000 500. OCO 200. OCO 500.000 200. oca SCO. 000 200.000 500.000 200. OCO 500.000 200.000 500.000 O.OCO 2CO.OOO 32.800 200.000 33.600 2CO.OOO 34.400 200.000 35.200 200.000 36.000 200.000 36.800 200.000 37.600 200.000 38.400 200.000 39.200 200.000 40.000 200.000 41.300 200.000 42.700 200.000 44.000 200.000 45.400 200.000 46.700 200.000 48.100 0.000 1.000 503.500 1.000 503. SCO 1.000 503.500 1.000 503.500 1.000 503.500 1.000 503.500 1.000 503.500 1.000 503.500 1.000 503.500 1.000 503.500 1.000 503. SCO 1.000 503.500 1.000 503. SCO 1.000 503.500 l.OCO 503.500 1.000 503.500 0.000 0.000 43. POO O.OCO 44.600 0.000 45.40C O.COO 46.200 0.000 47,000 0.000 47.800 0.000 4B.600 0.000 49.400 0.000 50.200 0.000 51.000 0.000 52.300 0.000 53.700 0.000 55.000 0.000 56.400 0.000 57.700 0.000 59.100 0.000 O.OCO 520.000 0.000 520. OCO 0.000 520.000 0.000 520. OCO 0.000 520.000 O.OCO 520.000 0.000 520.000 O.OCO 520.000 0.000 520.000 0.000 520.000 0.000 520.000 0.000 520.000 0.000 520.000 0.000 520.000 0.000 520.000 0.000 520.000 0.000 l-JUL-89 PAGE SECNO Q TIME SLOPE OEPTH QL08 VLOB XLQBL CWSEL CRIUS QCH QRDB VCH VRDB XLCH XLCB» WSELK EG ALCB ACH XNL XNCH ITRIAL IDC HV HL AROB VOL XNR UTN ICON! COBiR CLCSS SANK etev TWA LEFT/BIGHT ELPIN SSTA TCPHID ENDST *PRCF 1 CCHV- 0.200 CEHV* 0.400 *SECNO 20.000 3720 CRITICAL DEPTH ASSUMED 3*70 ENCROACHMENT STATIOKS" 220.0 370.0 TYPE- OOhNSTREAM FACE OF EL CAHIhO REAL 20.00 8.67 38.17 38.17 40.50 41.56 9850, 0. 9850. 0. 0. 667. 0.00 0.61 14.77 0.61 0.040 0.030 0.007383 0. 0. 0. 0 1* TARGET' 3.39 0. 0.040 0 0.00 0. 0.000 0.00 150.000 0.00 0. 24.50 102.82 38.00 38.00 248.59 351.41 SPECIAL BRIDGE 522T DOWNSTREAM ELEV IS SB XK 1.05 XKQR 1.80 36.27 ,NDT CCFQ 3.00 RDLEN ISO.00 38.17 HYDRAULIC JU*P OCCURS DOWNSTREAM (IF LOW FLOW CCNTROLS) BHC 70.00 BWP 4.00 BARE* 1020.00 SS 2.00 ELCHU 29.50 *SECNO 20.100 3301 HV CHANGED MORE THAN HVIhS CLASS 8 LOW FLOW 3420 BRIDGE W.S.* 37.61 8PIDGE VELOCITY** EGPRS EGLWC h3 CUEIR CLOW TRAPEZCID AREA 0.00 *1.73 0.00 0. 9850. 1020. 1208. 42.60 44.00 ELCHD 29.50 14.77 CALCULATED CHANNEL ABEA-, 667. BAREA TRAPEZCID ELLC ELTRO 20.10 9850. 0.00 0.004504 UPSTftEAH FACE CF EL CAHNO REAL 9.72 11. 1.79 110. 39.22 9828. 12.72 110. 0.0011. 1.79 110. 0.00 6. 0.040 0 41.73 2.51 0.18 0.00 3B.OO 772. *. 2. 0. 38.00 0.030 0.040 0.000 2S.50 239.80 0 0 0.00 120.41 360.20 VSECNO 21.000 l-JUL-89 20:45:*9 PAGE SECNO Q TIME SLOPE DEPTH DLCB VL09UOBL CWSEL CCM VCM XLCH CRIWS CRQB VRD8 XLOBR WSEUK EG ALCB BCH XNL XNCH ITRIAL IDC HV HL AROB VOL XNR WTN ICONT CORBR Ot-CSS B4NK. ELEV TWA LEFT/RIGHT ELPIN 5STA TOPWIO ENDST 3280 CROSS SECTION 21.00 EXTEhDED 0.43 FEET 3301 MV CHANGED MORE THAN HVINS 7185 M-INIHUM SPECIFIC ENERGT 3720 CRITICAL DEPTH ASSUMED 3470 ENCROACHMENT STATIOKS- 21.00 10.93 39.93 9850. 0. 9723. 0.01 0.00 15.43 0.006323 190. 170. 260.0 39.93 127. 3.70 160. 360.0 0.00 0. 0.000 4 TYPE" 43.58 630. 0.030 8 1 TARGET- 3.65 34. 0.040 0 0.90 5. 0.000o.co 100.000 0.46 1. 29.00 100.00 37.50 37.50 260.00 360.00 *SECNO 22.000 3301 HV CHANGED MORE THAN HVINS 3470 ENCROACHMENT STATIONS- 22.00 11.01 42.01 8080. 0. 7639. 0.01 0.00 14.15 0.005452 230. 215. 116.0 0.00 441. 6.47 190. 220.0 0.00 0. 0.000 5 TYPE- 44.98 540. 0.030 0 1 TARGET- 2.97 68. 0.040 0 1.26 8. 0.000 0.00 104.000 0.14 1. 31.00 86.27 42.00 34.00 116.00 202.27 *SECNO 23.000 3265 DIVIDED FLOW 3*01 HV CHANGED MORE THAN HVIKS 3470 ENCROACHMENT STMIChS- 23.00 12.23 43.73 8080. 9. 8040. 0.01 1.82 11.12 0.003079 125. 121. 198.0 0.00 31. 1.68 113. 430.0 0.00 5. 0.040 3 TYPE* 45.68 717. 0.030 0 1 TARGET- 1.S4 18. 0.040 0 0.48 10. 0.000 0.00 232.000 0.21 1. 31.50 144.30 42.00 42.00 198.98 404.20 l-JUL-89 20:45:4?PAGE SECNO DEPTH Q QLOB TIKE VLOB SLOPE XLOSL CWSEL OCH VCM XLCh CRGfi VKOB WSELK EG ALCB *CH XNL KNCH ITHIAL IOC HV ML •BOB VOL XMR KTti ICON! CCRAff DLCSS BAKU ELEV TWA LEFT/BIGHT ELKIN SSTATOPWID ENDST *SECNO 24.000 3301 HV CHANGED WORE THAN HVINS 3*70 ENCRCiCHfEM STATIONS 2*.00 11.57 80BO. 0. 0.02 0.00 0.005193 145. *SECNO 25.000 3280 CROSS SECTION 3470 ENCROACHMENT STATIONS 25.00 11.45 8080. 31. 0.02 1.37 0.004209 165. OKS- 3.87 OC1. 3.03 137. 2S.OO OKS- 4.85 0*9. 2.46 157. 300.0 43.27 79. 2.56 120. EXTENDED 300.0 0.00 0. 0.00 145. 450.0 0.00 0. 0.000 4 0.35 500.0 0.00 22. 0.040 3 TTPE- 46.48 614. 0.030 6 FEET TYPE- 47.25 646. 0.030 0 1 TARGET 2.61 31. 0.040 0 0 1 TARGET 2.40 0. 0.000 0 0 • 0.54 12. .000 0.00 z 0.73 14. .000 0.00 150.000 0.27 2. 32.30 117.53 200.000 0.04 2. 33.40 129.46 44.00 42.00 3C8.30 425.82 44.00 100000.00 370.54 500.00 *SECNO 26.000 3280 CROSS SECTION 26.00 EXTENDED 0.29 FEET 3301 HV CHANGED MORE THAN HVINS 3470 ENCROACHMENT STATIONS- 26.00 11.18 46.68 3080. 58. 7634. 0.03 1.44 10.64 0.002638 305. 305. *SECNC 27.000 3470 ENCROACHMENT STATIONS- 27.00 11.71 47.71 8080. 357. 7658. 0.03 3.42 9.46 0.002041 245. 245. 440.0 0.00 189. 3.21 302. 580.0 0.00 £6. 1.66 245. 650.0 0.00 40. 0.040 2 750.0 0.00 104. 0.040 2 TYPE* 48.39 73«. 0.030 0 TYPE- 49.04 609. 0.030 0 1 TARGET 1.71 59. 0.040 0 0 X 1.00 19. .000 0.00 1 TARGET" 1.33 40. 0.040 0 0 0.57 24. .COO 0.00 210.000 0.14 3. 35.50 196. B2 170.000 0.08 4. 36.00 170.00 44.00 44.00 453.18 650.00 44.00 46.00 580.00 750. 00 l-JUL-69 20:45:49 PAGE SECNO DEPTH CWSEL Q OLOB CCH TIKE VLQB VCH SLOPE XL06L XLCH 4SECNC 28.000 3*70 ENCROACHMENT STATIONS- 28.00 11.44 40.4* 8080. 457. 7618. 0.04 2.75 8.80 0.001922 254. 254. *SECKO 29.000 3470 ENCROACHMENT STATIONS" 29.00 11.46 49.06 8060. 388. 7678. 0.05 2.42 8.12 0.001413 262. 264. *S£CNQ 30.000 3470 ENCROACHMENT STATIONS* 30.00 10.98 49.28 8080. 278. 7712. 0.06 2.10 B.2B 0.001528 150. 168. *SECNO 31.000 3470 ENCROACHMENT STATIONS* 31.00 10.73 49.43 8080. 308. 7772. 0.06 2.51 8.71 0.001835 127. 130. •SECNO 32.000 3470 ENCROACHMENT STAT10NS- 32.00 9.98 49.78 8080. 0. 8080. 0.07 0.00 10.01 0.002982 265. 260. CRUS QRCfi VRCB XLOBR 750.0 0.00 5. 0.76 254. 800.0 0.00 14. 0.92 266. 900.0 0.00 20. 1.20 185. 950.0 0.00 0. 0.00 137. 11BO.O 0.00 0. 0.00 253. WSELK BLOB XNL ITPIAL 950.0 0.00 166. 0.040 2 1000.0 0.00 160. 0.040 2 1100.0 0.00 132. 0.040 2 1150.0 0.00 123. 0.0*0 2 1380.0 0.00 0. 0.000 2 EG ACM XNCH IDC TTPE- 49.58 866. 0.030 0 TYPE- 50.04 945. 0.030 0 TTPE- 50.31940. 0.030 0 TYPE" 50.57 893. 0.030 0 TYPE" 51.34 807. 0.030 0 HV ABOB XNR ICON! HL VOL UfH CORAR 1 TARGET- 1.14 7. 0.040 0 0.50 30. O.COO o.oo 1 TARGET- 0.36 15. 0.040 0 0.43 37. 0.000 0.00 1 TARGET* 1.03 17. 0.040 0 0.25 *1. 0.000 0.00 1 TARGET- 1.14 0. 0.000 0 0.22 44. 0.000 0.00 1 TARGET- 1.56 0. O.OCO 0 0.60 50. 0.000 0.00 OLCSS TWA ELKIh TCPWIO 200.000 0.04 6. 37.00 20C.OO 200.000 0.03 7. 37.60 198.22 200.000 C.02 8. 38.30 200.00 200.000 0.04 8. 3B.TO 168.69 200.000 0.17 9. 39.80 110.20 BAhK ELE LEFT/PIGMT SSTA END5T 46.00 48.00 750.00 9*0.00 46.00 46.00 SCO. 00 998.22 46.00 4S.OO 9CO.OO 1100.00 46.00 50.00 9SO.OO 1119.69 :o.oo 54.00 1255.49 1365.69 l-JUL-89 20:*5:*9 PAGE 10 SECNQ DEPTH CWSEL CBIfcS 0 QLOB QCH QRGB TIKE VLDB VCH VRC8 SLOPE XLQBL XLCH XLCBR HSELK EG ALdB ACH XNL XNCH ITRIAl IDC HV HL OLCSS BANK ELEV AROfl VOL TWA LEFT/RIGHT XNR U1H ELMIN SSTA ICONT CORAR TOPWIO ENDST *SECNO 33.000 3301 MV CHANGED MORE THAN HVIKS 3685 20 TRIALS ATTEMPTED USEL,CUSEL 3693 PROBABLE MINIMUM SPECIFIC ENERGY 3720 CRITICAL DEPTH ASSUMED 3*70 ENCROACHMENT STATIOKS- 33.00 11.35 SI.25 SOBO. IT. 8063. 0.07 2.28 15.04 0.007036 52. 45. 1180.0 51.25 0. 0.00 4S. 1350.0 0.00 7. 0.0*0 20 TYPE- 5*. 76 536. 0.030 3 1 TARGET- 3.50 0. O.OCO 0 0.20 SO. 0.000 0.00 170.000 0.78 9. 39.90 85.60 50.00 54.00 1187.08 1272.68 *SECNO 34.000 3665 20 TRIALS ATTEMPTED WSELtCWSEL 3693 PROSABLS MINIMUM SPECIFIC ENERGY 3720 CRITICAL DEPTH ASSUMED 3470 ENCROACHMENT STATIONS" 34.00 10.29 52.79 8080. 0. 8080. 0.07 0.00 15.22 0.007*6* 135. 130. 1250.0 52.79 0. 0.00 125. 1*20.0 0.00 0. 0.000 20 TYPE- 56.39 531. 0.030 11 1 TARGET- 3.60 0. O.OCO 0 0.9* 52. 0.000 0.00 170.000 0.04 9. 42.50 75.13 56.00 56.00 1264.73 1339.67 *SECNQ 35.000 3301 HV CHANGED MORE THAN HVIKS 3*70 ENCROACHMENT STATIONS- 1251.0 35.00 11.60 54.60 0.00 80BO. 0. 8078. 2. 0.07 0.00 12.75 1.15 0.00*780 91. 88. 68. 1*00.0 TTPE- 0.00 57.12 0. 63*. 0.000 0.030 * 0 1 TARGET- 2.52 0.52 2. 53. 0.0*0 0.000 0 0.00 1*9.000 0.21 9. 43.00 89.81 58.00 5*.00 1258.64 1348.*5 *SECNO 36.000 3301 HV CHANGED MORE THAN HVUS i i I i I I I i I i i I i I i I i I I I i I i I i t I-JUL-89 20:45:49 II SECNO DEPTH CWSEL Q QIOB QCH TIME VLDB VCH SLOPE XLOBL XLCh CfilWS WSELK EG QRC6 ALCB ACH VRC8 XM. XNCH XLCBR ITRIAL IDC HV ML ARCS VOL XNR UTN ICON7 CORAR OLCSS BAMl ELEV ThA LEFT/RIGHT ELfIN SSTA TQPWID ENOST 3*70 ENCROACHMENT ST«TIOkS- 36.00 12.10 56.00 BOSO. 0. 8090. O.OB 0.00 10.460.002856 121. 114. 1235.0 0.00 0. 0.00 107. 1350. 0 0.00 0. 0.000 3 TTPE- 57.70 772. 0.030 0 1 TARGET- 1.70 0. O.OCO 0 0.41 55.o.coo 0.00 115.000 0.16 10. 4?. 90 93.99 £8.00 56.00 1239.00 1333.00 4SECNO 37.000 3301 HV CHANGED MORE THAN HVIHS 3470 ENCROACHMENT STATIONS" 1300.0 1520.0 TYPE- 37.00 11.31 55.81 0.00 0.00 58.37 8080. 0. 8080. 0. 0. 629. 0.08 C.OO 12.84 0.00 0.000 0.030 0.004673 96. 90. 85. 3 0 1 TARGET- 2.56 0.32 0. 56. 0.000 0.000 0 0.00 220.000 0.3* 56.00 10. 56.00 44.50 1423.40 79.26 1502.65 SPECIAL BRIDGE 5227 DOWNSTREAM ELEV IS SB XK 1.20 XKOR 1.25 53.98 .NOT COFQ 3.00 *SECNO 33.000 3301 HV CHANGED HORE THAN HVIKS PRESSURE AND UEIA FLCH ROLEN 0.00 55.81 HYDRAULIC JUNP OCCURS DOWNSTREAM CIF LOW FLOW CONTROLS) BMC 39.00 BMP 1.70 BAREA 396.00 SS 0.00 EICMU 44.50 ELCHO 44.50 EGPRS 63.69 EGLWC 61.29 H3 0.00 CHEIR 251«. OPR 5596. BAREA 396. TRAPEZDIO AREA 417. ELLC 56.00 ELTRD 58.00 3470 ENCROACHMENT STATIOKS- 38.00 13.69 58.19 8080. 87. 7993. 0.08 2.27 9.85 0.002002 46. 46. 1400.0 0.00 0. 0.00 46. 1500.0 0.00 36. 0.040 3 TYPE" 59.69 811. 0.030 0 1 TARGET" 1.49 C. 0.000 5 1.32 57. 0.000 0.00 100.000 0.00 10. 44.50 100.00 56.00 100000.00 14CO.OO 15CO.OO t i i i i i i i I i i I i i t i i i i t i t i ft l i i f I i l-JUL-89 PAGE 12 SECNQ DEPTH Q QLOB TIfE VLDB SLOPE KLOBL CWSEU GCH VCM XLCh CRIUS QRC6 vnce XLCBR WSELK EG ALOe ACH XNL KNCH ITfiliL IDC HV ML CLCSS SAMC ELEV ARCB VOL TU« LEFT/RIGHT XNR WTN ELMIN SST« ICON! CORAR TOFHID ENDST *S£CNO 39.000 3265 DIVIDED FLOW 3301 HV CHANGED MORE THAH HVUS 39.00 12.97 59.17 0.00 0.00 59.93 0.77 0.10 0.15 56.00 9000. 566. 5635. 1797. 346. 692. 537. £9. 11. 56.00 0.08 1.64 9.14 3.35 0.035 0.030 0.035 0.000 46.20 260.14 0.001373 61. 62. 68. 4 0 0 0.00 706.95 1617.01 •SECNQ 40.000 3685 20 TRIALS ATTEMPTED USEL.CUSEL 3693 PROBABLE MINIMUM SPECIFIC ENERGY 3T20 CRITICAL DEPTH ASSUMED 3470 ENCROACHMENT STATIONS' 40.00 12.31 59.31 8000. 431. 4769. 0.09 1.94 10.43 0.002807 69. 78. 1050.0 59.31 2800. 4.07 87. 1670.0 0.00 222. 0.035 20 TYPE- 60. '1 457. 0.030 10 1 TARGET- 1.10 686. 0.035 0 0.15 62. 0.000 0.00 620.000 0.13 12. 47.00 620.00 58.00 56.00 1050.00 1670.00 *SECNO 41.000 3685 20 TRIALS ATTEMPTED WSEL.CWSEL 3693 PROBABLE MINIMUM SPECIFIC ENERGY 3720 CRITICAL DEPTH ASSUMED 3470 ENCROACHMENT STATIONS- 41.00 12.15 60.35 8000. 1704. 4597. 0.09 2.91 9.81 0.002*05 112. 120. 940.0 60.35 1699. 2.92 125. 1700.0 D.OO 586. 0.035 20 TYPE- 61.26 469. 0.030 6 1 TARGET- 0.91 581. 0.035 0 0.31 66. 0.000o.oo 760.000 0.04 58.00 14. 56.00 48.20 940.00 760.00 1700.00 CCHV- 0.100 CEHV *SECND -21.000 START TPIB COUP -21.000 -21.00 1740. 0.10 0.00 0.008071 200, 0.300 21.000 39.933 7.93 39.93 0.00 0. 1740. 0. 11.61 200. 0.00 200. 0.00 42.02 2.09 0.00 0.00 43.00 0. 150. 0. 70. 15. 43.00 0.000 0.030 O.OCO 0.000 32.00 464.60 000 0.00 3C.80 515.40 I I I I I i I I I I I I I I I I i I I i I Iflllilillliii l-JUL-89 PAGE 13 SeCNO DEPTH Q 0108 TIKE VLOB SLOPE XLOBL CMSEL CKIKS GCH QOCB VCH VRCB XLCH XLOGR WSELK EG ALDB ACH XNL XNCH ITRIAL IOC HV ML AROB VOL XNR UTN ICONT CORAR OLOSS BANK ELEV TWA LEFT/RIGHT ELfIN SSTA TOPWID ENCST tSECNO 1.000 3301 HV CHANGED MORE THAfc HVtKS 1.00 1740. 0.10 0.004293 *SECNO 2.000 2.00 1740. 0.11 0.004131 *SCCNO 3.000 3.00 1740. 0.11 0.004060 *SECNO 4.000 4.00 1740. 0.12 0.004033 tSECNO 5.000 5.00 1740. 0.13 0.004021 *SECNO 6.000 6.00 1740. 0.13 0.004012 9.15 0. 0.00 200. 9.2S 0. 0.00 200. 9.27 0. 0.00 200. 9.28 0. 0.00 200. 9.29 0. 0.00 200. 9.30 0. 0.00 200. 41.95 1740. 9.16 200. 42.83 1740. 9.03 200. 43.67 1740. 8.97 200. 44.46 1740.a. 95 200. 45.29 1740. 8.94 200. 46.10 1740. 8.94 200. 0.00 0. 0.00 200. 0.00 0. 0.00 200. 0.00 0. 0.00 200. 0.00 0. 0.00 200. 0.00 0. 0.00 200. 0.00 0. 0.00 200. 0.00 0. 0.000 2 0.00 0. 0.000 2 0.00 0. 0.000 0 0.00 0. 0.000 0 0.00 0. 0.000 0 0.00 0. 0.000 0 43.25 190. 0.030 0 44.10 193. 0.030 0 44.92 194. 0.030 0 45.73 194. 0.030 0 46.53 195. 0.030 0 47.34 195. 0.030 0 1.30 0. 0.000 0 1.27 C. 0.000 0 1.2S 0. 0.000 0 1.24 0. 0.000 0 1.24 0. O.OCO 0 1.24 0. O.OCO 0 1.15 71. 0.000 0.00 0.84 71. 0.000 0.00 0.82 72. 0.000 0.00 0.81 73. O.COO 0.00 0.91 74. 0.000 0.00 0.80 75. 0.000 0.00 o.oa 16. 32.80 3*.47 0.00 16. 33.60 34.71 0.00 16. 34.40 34.82 0.00 16. 35.20 34.86 0.00 16. 36.00 34.88 0.00 16. 36. BO 34.89 43.80 43. BO 482.76 517.24 44.60 44.60 482.65 517.35 45.40 45.40 482.59 517.41 46.20 46.20 462.57 517.43 47.00 47.00 482.56 517.44 47.80 47.80 482.55 517.45 i i t i Illlllllitlli!fillllltlilili i i i l-JUL-89 20:45:49 PAGE 14 SECNO 0 TIHE SLOPE *SECNO 7. 7.00 1740. 0.14 0.00400S *SECNO 8. 8.00 1740. 0.1S 0.004002 *SECNO 9. 9.00 1740. 0.15 0.004001 *SECNO 10 10.00 1740. 0.16 0.004000 *SECNO 11, 11.00 1740. 0.16 0.005347 DEPTH OLOB VLOB UOBL 000 9.30 0. 0.00 200. 000 9.30 0. 0.00 200. 000 9.30 0. 0.00 200. .000 9.30 0. 0.00 200. .000 8.71 0. 0.00 200. CWSEL QCH VCH XLCH 46.90 1740. 8.93 200. 47.70 1740. 8.93 200. 48.50 1740.e.93 200. 49.30 1740. 8.93 200. 50.01 1740. 9.95 200. CRIUS QROB VROB XLOBR 0.00 0. 0.00 200. 0.00 0. 0.00 200. 0.00 0. O.QQ 200. 0.00 0. 0.00 200. 0.00 0. 0.00 200. WSEIK ALOB XM ITRIAL 0.00 0. 0.000 0 0.00 0. 0.000 0 0.00 0. 0.000 0 0.00 0. 0.000 0 0.00 0. 0.000 2 EG *CH XNCH IDC 48.14 195. 0.030 0 48.94 195. 0.030 0 49.74 195. 0.030 0 50.54 195. 0.030 0 51.55 175. 0.030 0 HV ARQ9 XNR ICONT 1.24 0. 0.000 0 1.24 0. 0.000 0 1.24 0. o.oco 0 1.24 0. 0.000 0 1.S4 0. O.OCO 0 HL VOL hTN CCRAR 0.80 76. 0.000 0.00 0.80 77. 0.000 0.00 0.10 78. 0.000 0.00 0.80 79. 0.000 0.00 0.92 79. 0.000 0.00 OLCSS TWA ELHIN TCPWIO 0.00 16. 37.60 34.90 0.00 IT. 38.40 34.91 0.00 17. 39.20 34.91 0.00 17. 40.00 34.91 0.09 17. 41.30 33.14 BAMC ELEV LEFT/HIGHT SSTfl ENCST 48.60 48.60 482.55 517.45 49.40 49.40 482.55 517.45 50.20 50.20 482.55 517.45 51.00 51.00 482.55 517.45 52.30 52.30 483.43 516.57 *SECNO 12.000 12.00 1740. 0.17 0.006564 9.32 0. 0.00 200. 51.02 1740. 10.7* 200. 0.00 0. 0.00 200. 0.00 0. 0.000 2 52.81 162. 0.030 0 1.79 0. 0.000 0 1.18 80. 0.000 0.00 0.08 17. 42.70 31.95 53.70 53.70 484.02 515.98 iiliiililiifiiii I l I i I i t I i I i i i i i i i l-JUL-89 20:45149 15 SECNO DEPTH CWSEL Q GLOB QCH TIME VLD8 VCH SLOPE XLOflU JtLCH 4SECNC 13.000 13.00 9.34 1740. 0. 0.17 0.00 0.006510 200. •SECNO 14.000 14.00 8.22 1740. 0. 0.000.18 0.006908 200. *SECNO 15.000 15.00 8.36 1740. 0. 0.18 0.00 0.006402 200. *SECNO 16.000 16.00 8.22 1740. 0. 0.19 0.00 0.006906 200. 52.34 1740. 10.71 200. 53.62 1740. 10.95 200. 5S.06 1740. 10.64 200. 56.32 1740. 10.95 200. CfilkS QftOB VRQB XLCBR 0.00 0. 0.00 200. 0.00 0. 0.00 200. 0.00 0. 0.00 200. 0.00 0. 0.00 200. U5EL.K it. OB XNL ITRIAL 0.00 0. 0.000 2 0.00 0. 0.000 2 0.00 0. 0.000 2 0.00 0. 0.000 2 EG 1CH XNCM IOC 54.12 162. 0.030 0 55.48 159. 0.030 0 56.82 163. 0.030 0 58. IB 159. 0.030 0 HV ARCS XNR ICONT 1.78 0. 0.000 0 1.66 C. 0.000 0 1.76 0. 0.000 0 1.86 0. 0.000 0 HL VOL WTN CQR4R 1.31 81. 0.000 0.00 1.34 82. 0.000 0.00 1.33 82. 0.000 0.00 1.33 83. O.COO 0.00 OLCSS TWA ELHIH TDPWIO c.oo 17. 44.00 32.00 C.02 18. 45.40 31.66 0.01 18. 46.70 32.09 0.03 IB. 48.10 31.66 BAKK ELE LEFT/RIGHT SSTA ENDST 55.00 55.00 484.00 516.00 56.40 56.40 484.17 515.83 57.70 57.70 483.95 516.05 59.10 59.10 484.17 515.83 i i I I I I i i i i I i I i I I i i I I i I i i 1 ! i i l-JUL-89 20:45:49 PAGE 16 TUS BUN EXECUTED l-JUL-59 20:4£:07 **************************************************HEC2 RELEASE DATED NOV 76 UPDATED HAT 1984 ERROR CORK - 01 ,02,03.04,05t06 MODIFICATION - 50,51,£2.53,54,55 A************************************************* NOTE- ASTERISK c*) AT LEFT of CROSS-SECTION NUMBER INDICATES MESSAGE IN SUMMARY OF ERRORS LIST HOWARD H. CHANG, JUN SUMMARY PRINTOUT TABLE 150 * * * * * secNO 20.000 20.100 21.000 22.000 23.000 24.000 25.000 26.000 27.000 28.000 29.000 30.000 31.000 32.000 33.000 34.000 35.000 XLCH 0.00 110.00 170.00 215.00 121.00 137.00 157.00 305.00 245.00 254. CO 264.00 16B.OO 130.00 260.00 45.00 130.00 88.00 ELTRD 0.00 44.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 ELLC 0.00 42.60 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 ELHIN 29.50 29.50 29.00 31.00 31.50 32.30 33.40 35.50 36.00 37.00 37.60 38.30 38.70 39.80 39.90 42.50 43.00 0 9850.00 9850.00 9850.00 8080.00 8080.00 8080.00 8080.00 6080.00 6080.00 8080.00 8080.00 8080.00 8080.00 8080.00 8080.00 8080.00 8080.00 CWSEL 38.17 39.22 39.93 42.01 43.73 43.87 44.85 46.68 47.71 48.44 49.06 49.28 49.43 49.78 51.25 52.79 54.60 CRIWS 38.17 0.00 39.93 0.00 0.00 43.27 0.00 0.00 0.00 0.00 0.00 0.00 O.OC 0.00 51.25 E2.79 0.00 EG tl.56 41.73 43.58 44.98 45.68 46.48 47.25 48.39 49.04 49.58 50.04 50.31 50.57 51.34 54.76 56.39 57.12 10K*S 73.83 45.04 63.23 54.52 30.79 51.93 42.09 26.38 20.41 19.22 14.13 15.28 18.35 29.82 70.38 74.64 47.60 VCH 14.77 12.72 15.43 14.15 11.22 13.03 12.46 10.64 9.46 8.80 8.12 8.28 8.71 10.01 15.04 15.22 12.75 ARE* 667.14 784.95 664.55 6C7.99 740.28 644.99 668.41 834.83 953.12 1038.68 1120.92 1088.74 1015.66 607.29 543.69 531.02 635.29 .OIK 1146.37 1467.7* 1238. 7T 1094.30 1456.13 1121.27 1245.44 1573.12 1788.59 1842.85 2149.77 2066.75 1BS6.47 1479.56 963.12 935.26 116B.64 I I I I ililillllii!I i I i I I I I i I I I i I i I I l-JUl-89 PAGE 17 SECNO 36.000 37.000 * 38.000 39.000 * 40.000 * 41.000 -21.000 1.000 2.000 3.000 4.000 5.000 6.000 7.000 8.000 9.000 10.000 11.000 12.000 13.000 14.000 15.000 16.000 XLCH 114.00 90.00 46.00 62.00 78.00 120.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 ELTBD 0.00 0.00 58.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 ELLC 0.00 0.00 56.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 ELKIN 43.90 44.50 44.50 46.20 47.00 48.20 32.00 32.80 33.60 34.40 35.20 36.00 36.80 37.60 38.40 39.20 40.00 41.30 42.70 44.00 45.*0 46.70 48.10 Q 8080. OC 8080.00 8080.00 8000. CC 8000.00 8000.00 1740. CO 1740.00 1740.00 1740.00 17*0.00 17*0.00 1740.00 17*0. OC 1740.00 17*0.00 1740.00 174Q.OO 17*0.00 1740.00 17*0.00 1740. CC 1740.00 CWSEL 56.00 55.81 58.19 59.17 59.31 60.35 39.93 41.95 42.83 *3.67 44.48 45.29 46.10 46.90 47.70 48.50 49.30 50.01 51.02 52.34 53.62 55.06 56.32 CRIHS 0.00 0.00 0.00 0.00 59.31 60.35 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 EG 57.70 58.37 59.69 59.93 60.41 61.26 42.02 43.25 44.10 44.92 45.73 46.53 47.3* 48.1* 48.9* *9.7* 50.5* 51.55 52.81 54.12 55.48 56.82 58.18 10KSS 28.56 46.73 20.02 13.73 28.07 24.05 80.71 42.93 41.31 40.60 40.33 *0.21 *0.12 *0.05 40.02 40.01 40.00 53.47 65.64 65.10 69.08 64.02 69.06 VCM 10.46 12.84 9.85 3.14 10.43 9.81 11.61 9.16 9.03 8.97 8.95 8.9* 8.9* 8.93 8.93 8.93 8.93 9.95 10.74 10.71 10.95 10.6* 10.95 AREA 772.30 629.4* 849.59 1575.70 1367.37 1635.61 149.93 169.87 192.62 193.88 194.35 194.57 19*. 73 19*. 85 194.92 194.9* 19*. 9* 174.88 161.98 162.47 158.91 163.50 158.93 .OIK 1511.8* 1182.01 1E05.75 2158.91 1510.08 1631.** 193.68 265.57 270.73 273.09 273.99 27*. 40 274.70 27*. 93 275.06 275.10 275.10 237.95 21*. 77 215.65 209.35 217. *7 209.38 I I I I I I I I I I I I I I I iiiilililillliijii l-JUL-89 20:45:49 PAGE 18 HOWARD H. CHAM;, JUN SUMMARY PRINTCJT TABLE 150 * * * * * a * « 5ECNO 20.000 20.100 21.000 22.000 23.000 24.000 25.000 26.000 27.000 28.000 29.000 30.000 31.000 32.000 33.000 34.000 35.000 36.000 37.000 38.000 39.000 40.000 41.000 -21.000 Q 9850.00 9850.00 9B50.00 8080.00 8080. CO 8080.00 8080.00 8060.00 8080.00 8080.00 8080.00 8080.00 8080.00 8080.00 80BO.OO 8080.00 8080.00 8080.00 8080.00 8080.00 8000.00 6000.00 8000.00 1740.00 CUSEL 38.17 39.22 39.93 42.01 43.73 43.87 44.85 46.68 47.71 48.44 49.06 49.28 49.43 *9.7B 51.25 52.79 5*. 60 56.00 55.61 58.19 59.17 59.31 60.35 39.93 DIFHSP 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 DIFWSX 0.00 1.06 0.71 2.08 1.72 0.14 0.98 1.83 1.03 0.73 0.63 0.22 0.15 0.35 1.47 1.54 1.81 1.40 -0.19 2.38 0.97 0.14 1.04 -20.41 DIFKWS -2.33 0.00 o.co o.oc 0.00 0.00 0.00 0.00 0.00 0.00 0.00 o.oc 0.00 0.00 0.00 o.co o.oc o.cc 0.00 0.00 0.00 o.oc 0.00 0.00 TOPWID 102.82 120. *1 100.00 86.27 144.30 117.53 129.46 196.82 170.00 200.00 198.22 200.00 168.69 110.20 as. 60 75.13 89.81 93.99 79.26 100.00 706.95 620.00 760.00 30.80 XLCM 0.00 110.00 170.00 215.00 121.00 137.00 157.00 305.00 245.00 254.00 264.00 168.00 130.00 260.00 45.00 130.00 68.00 114.00 90.00 46.00 62.00 78.00 120.00 200.00 I i I i I i I I I I I I I I I I ] 1 i i i I 1 I I I l I I i I I I-JUL-89 20145:49 PAGE 19 SECNO 1.000 2.000 3.000 4.000 5.000 6.000 7.000 8.000 9.000 10.000 11.000 12.000 13.000 14.000 15.000 16.000 0 1740.00 1740.00 1740.00 1740.00 1740.00 1740.00 1740.00 1740.00 1740.00 1740.00 1740.00 1740.00 1740.00 1740.00 1740.00 1740.00 CWSEL 41.95 42. S3 43.67 44. 48 45.29 46.10 46.90 47.70 48.50 49.30 SO. 01 51.02 52.34 53.62 55.06 56.32 DIFWSP 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 DIFhSX 2.01 O.B8 O.S4 O.B2 0.61 0.81 0.80 0.80 0.80 0.80 0.71 1.00 1.32 1.28 1.44 1.26 OIFKHS 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 TOPKID 34.47 34.71 34.62 34. 86 34.88 34.B9 34.90 34.91 34.91 34.91 33.14 31.95 32.00 31.66 32.09 31.66 XLCM 2CO.OO 200.00 200.00 2CO.OO 200.00 2CO.OO 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 200.00 till I I i I I I I I I 1 i 1 1 I 1 I I I I I I I i i I I I l-JUL-89 PAGE SUMMARY CF ERRORS AND SPECIAL NOTES CAUTION CAUTION CAUTION CAUTION CAUTION CAUTION CAUTION CAUTION CAUTION CAUTION CAUTION CAUTION CAUTIONCAUTION CAUTION CAUTION CAUTION SECNC- SECNO» SECNO" SECNO* SECNO- SECNO- SECNC- SeCNO- SECNQ- SECNC- SECNC- SECNO" SECNO- SECNC- SECNO- SECNC- SECNO" 20.000 20.100 21.000 21.000 33.000 33.000 33.000 34.000 34.000 34.000 38.000 40.000 40.000 40.000 41.000 41.000 41.000 PRCFILE* PROFILE" PROFILE- PROFILE" PROFILE- PROFILE- PROFILE* PROFILE- PROFILE" PROFILE- PROFILE" PROFILE- PROFILE- PBDFILE- PROFILE- PROFILE- PROFILE" 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 CRITICAL DEPTH HYDRAULIC JUMP D.S. CRITICAL DEPTH ASSUMED MINIMUM SPECIFIC ENERGY CRITICAL DEPTH ASSUMED PROBABLE MINIMUM SPECIFIC ENERGY 20 TRIALS ATTEMPTED TO BALANCE USEL CRITICAL DEPTH ASSUMED PROBABLE MINIMUM SPECIFIC ENERGY 20 TRIALS ATTEMPTED TO BALANCE hSEL HYDRAULIC JUMP O.S. CRITICAL DEPTH ASSUMED PROBABLE MINIMUM SPECIFIC ENERGY 20 TRIALS ATTEMPTED TO BALANCE MSEL CRITICAL DEPTH ASSUMED PROBABLE MINIMUM SPECIFIC ENERGY 20 TRIALS ATTEMPTED TO BALANCE MSEL