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Home My WebLink AboutCT 2018-0006; LAGUNA DRIVE SUBDIVISION; PRELIMINARY GEOTECHNICAL INVESTIGATION PROPOSED 12 UNIT RESIDENTIAL STRUCTURES; 2018-04-04RECORD COPY COAST GEOTECHNICAL CONSULTING ENGINEERING GEOLOGISTS Apri14, 2018 RCllYI Brett Farrow Brett Farrow Architect 125 Mozart Avenue Cardiff, CA 92007 JUL 09 222 LAND DEVELOPMENT ENGfN"t à_. I RE: PRELIMINARY GEOTECHNICAL INVESTIGATION Proposed 12 Residential Structures 570-580 Laguna Drive Carlsbad, CA 92008 Dear Mr. Farrow: In response to your request and in accordance with our Agreement dated January 16, 2018, we have performed apreliminary geotechnical investigation on the subject site for the proposed 12 residential structures. The findings of the investigation, laboratory test results, and recommendations for the foundation des ign.are presented in this report. From a geologic and soils engineering point of view, it is our opinion that the site is suitable for the proposed development, provided the recommendations in this report are implemented during the design and construction phases. However, certain geotechnical conditions will require special consideration during the design and construction phases, as indicated by the following: The existing soil and weathered Paralic Deposits are not suitable for the support of proposed footings, slabs-on-grade, exterior improvements or proposed fills in their present condition. Remedial grading is recommended. P.O. BOX 230163 ENC1NITAS, CALIFORNIA 92023 (858) 755-8622 The rear inland bluff is composed, in part, of friable Paralic Deposits which are susceptible to surficial failure and bluff retreat. Surface drainage should be directed, as much as possible, away from the top of slope. The geologic conditions underlying the rear bluff are such that infiltrated water developing saturated conditions can adversely affect slope stability. Storniwater infiltration should be significantly limited and if necessary bioretention basins should be located in the most southern portion of the site. If you have ariy questions, please do not hesitate to cOntact us at (858) 755-8622-. This opportunity to be of service is appreciated. Respectfully submitted, COAST GEOTECHNICAL Wyatt Bartholomew Project Geologist MarkBwwell, C.E.G. Vithaya Siñghanet, P.E. Engineering Geologist Geotechiiical Engineer. PRELIMINARY GEOTECHNICAL INVESTIGATION Proposed 12 Residentil Structures 570-580 Laguna.Drive Carlsbad, CA 92008 Preparedfor Brett Farrow Brett Farrow Architect 125 MoaitAveñue Cardiff, CA 92007 Prepared by: COAST GEOTECH1TCAL P.O. Box 230163 Encinitas, CA 92023 April 4,2018 W.O. 686218 TABLE OF CONTENTS INTRODUCTION...........................................................6 SCOPE OF SERVICES ......................................................6 SITE DESCRIPTION AND PROPOSED DEVELOPMENT .........................7 3.1 Site Description .................................................. ......... 7 3.2 Proposed Development....................................................7 SITE INVESTIGATION AND LABORATORY TESTING ........................... 8 4.1 Site Investigation ................................................. . ........ 8 4.2 Laboratory Testing and Analysis ............................................8 4.3 Infiltration Testing .......................................................9 GEOLOGIC CONDITIONS ................................................... 9 5.1 Regional Geologic Setting .................................................9 5.2 Site Geology ...........................................................10 5.3 Expansive Soil .........................................................11 5.4 Groundwater Conditions .................................................. 11 GEOLOGIC HAZARDS ....................................................11 6.1 Faulting and Seismicity .......................... . ....... . ................. 11 6.2 Landslide Potential ......................................................13 6.3 Liquefaction Potential....................................................14 6.4 Tsunami Potential .................... ................ ................... 15 CONCLUSIONS............................................................15 RECOMMENDATIONS .....................................................16 8.1 Removals and Recompaction ..............................................16 8.2 Temporary Slopes and Excavation Characteristics................................ 17 8.3 Foundations ............................................................... 17 8.4 Sulfate and Chloride Tests .................................................18 8.5 Slabs on Grade (Interior and Exterior) ........................................18 8.6 Lateral Resistance ......................................................19 8.7 Retaining Walls ........................................................... 19 8.8 Dynamic (Seismic) Lateral Earth Pressures ...................................20 8.9 Settlement Characteristics ................................................... 21 8.10 Seismic Considerations....................................................21 8.11 Preliminary Pavement Design ................................... .......... 22 8.12 Permeable Interlocking Concrete Payers (PICP) ..............................23 8.13 Utility Trench ...........................................................24 8.14 Drainage ..............................................................24 8.15 Geotechnical Observations ..................................... .......... ..25 8.16 Plan Review ...........................................................25 LIMITATIONS .......................................................... 25 REFERENCES ................................................................27 COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page-.5--of 28 APPENDIX A Figure 1: Location Map Figure 2: Geotechnical Map Figure 3:. Cross SectionA-A" Figure 4 Borehole log N. 1 Figure 5: BOrehole Log NO. 2 Figure 6 Regional Fault Map Plate A: Typical IsOlation Joints àfld Re-Entrant Corner ReinfOcexnent, Plae;. Typical.Pàmeable Paver Detail APPENDIX:B Laboratory Test Results Figure 7: Double Ringlnfiliration Test* Data Figure 8: Infiltration Test Graph. Seismic Design Parameters Desi'. Re* sponse Spectrum APPENDIXC Slope Stability.Analysis APPENDIX D Grading . Gui del ines COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 6 of 28 INTRODUCTION This report presents the results of our background review, subsurface investigation, laboratory testing, geotechnical analyses, conclusions regarding the conditions at 570-580 Laguna Drive, and recommendations for design and construction. The purpose of this study is to evaluate the nature and characteristics of the earth materials underlying the property, the engineering properties of the surficial deposits and their influence on the proposed 12 residential structures. SCOPE OF SERVICES The scope of services provided included a review of background data, reconnaissance of the site geology, and engineering analysis with regard. to the proposed. The performed tasks specifically included the following: Reviewing geologic and hazard (seismic, landslide, and tsunami) maps, recently published regarding the seismic potential of nearby faults, and a site plan for the project. All background data is listed in the References portion.of this report. Performing a site reconnaissance, including the observation'of geologic conditions and other hazards, which may impact the proposed project. Excavation of exploratory borings consisting of excavating, logging, and sampling of earth materials to evaluate the subsurface conditions. Performing geotechnical laboratory testing of recovered soil samples. Analyzing data obtained from our research, subsurface exploration, and laboratory and infiltration testing. 9 Preparing this preliminary report. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 7 of 28 3. SITE DESCRIPTION AND PROPOSED DEVELOPMENT 3.1 Site Description The subject site is a partially developed lot on Laguna Drive in the city of Carlsbad (Figure 1). The northwest quadrant of the lot is vacant, the southeast quadrant of the lot is developed with a small building, the northeast and southeast quadrant hosts an existing building and the remainder of the. lot is paved with asphalt. The property is a polygonal-shaped area that descends gently to the northwest and is bounded by an inland bluff that descends to Buena Vista Lagoon. The elevation of the lot ranges from approximately 5.0 to 45 feet. The subject site includes an existing residence, existing office building, and two existing AC parking areas. The lot is relatively flat ranging from 40 to 43 feet as you move north to south along the property. The northern portion of the property is bounded by an inlaiid bluff that descends to the Buena Vista Lagoon at a gradient approaching 1¼: 1 (horizontal to vertical) for approximately 40 vertical feet. The site is bounded along the north by Buena Vista Lagoon, to the south by Laguna Drive, and to the east and west by developed residential lots. Vegetation on the site consists of trees and shrubs. Drainage is generally by sheet flow to the northwest in the direction of the inland bluff and Buena Vista Lagoon. 3.2 Proposed Development A topographic plat of the site was prepared by Sampo Engineering. Preliminary architectural plans for the development of the site were prepared by Brett 'Farrow, Architect. The project is anticipated to include the demolition of the most southeastern existing building, but not the northeastern structure, and the construction of 12 residential structures with one car garages (Figure 2). Grading plans were not available during the assessment of the lot, but due to the relatively flat nature of the existing lot, we presume grading to be minimal. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 8 of 28 4. SITE INVESTIGATION AND LABORATORY TESTING 4.1 Site Investigation Site exploration was performed on March 16,2018. It included a visual reconnaissance of the site and the excavation of two (2) exploratory boreholes (Figures 4-5). The boreholcswere drilled using a.truck-mounted hollow-stem auger. Samples were obtained tisinga modified California Sampler and SPT Sampler. All the borings were extended through the underlying top soil, Old Paralic Deposits and into the underlying Santiago Formation to maximum depths 50 feet in Borehole 1 and 36 feet in Borehole 2. Earth materials encountered were visually classified and logged by our field project geologist, and sampled for future laboratory testing. Undisturbed, representative samples of earth materials were obtained at selective intervals by driving a thin-walled steel sampler into the desired strata with a 140 pound hammer powered by a cathead and rope system. Bulk samples were also obtained at selected intervals. Samples are retained in waterproof containers and brass rings and transported to Coast Geotechnical Soils Laboratory for testing and analysis. The site investigation also included a visual Observation of the surrounding landscape of the project site. Existing wood retaining walls are in place along the slope into the lagoon. 4.2 Laboratory Testing and Analysis The laboratory tests were performed in accordance with the generally accepted American Society for-Testing and Materials (ASTM) test methods or suggested procedures. All lab descriptions and. results can be found in the Test Results section of Appendix B of this report. The following tests were preformed: Classification of Soils Grain Size Distribution. Moisture/Density COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 9 of 28 o Maximum Dry Density and Optimum Moisture Content Expansion Index Test Sulfate Ion Content Chloride Ion Content pH Test Field Resistivity Test Shear Test Infiltration Test 4.3 Infiltration Testing Infiltration testing was performed using a Double-Ring Inflitrometer (ASTM D3385). The infiltration test area is located in the southern portion of the site as indicated on the enclosed Geotechnical Map. The area was prepared by excavating down to the Paralic Deposits. A level pad was established for testing. Infiltration results can be found in the .Test Results section of Appendix B of this report as Figures 7 (Infiltration Test Log) and 8 (Infiltration Test Graph).. 5. GEOLOGIC CONDITIONS The geologic conditions at the site are based on our field exploration and review of available geologic and geotechnical. literature. 5.1 Regional Geologic Settings The subject property is located in the Coastal Plains subdivision of the Peninsular Ranges geomorphic province of San Diego. The coastal plain area.is characterized by Pleistocene marine terrace landforms. These surfaces are relatively flat erosional platforms that were shaped by wave action along the former coastlines. The step-like elevation of the marine terraces was caused by changes in sea level throughout the Pleistocene and.by seismic activity along the Newport-Inglewood Fault Zone located 4.5 miles west of the coastline. The Newport-Inglewood Fault Zone is one of many northwest trending, sub-parallel faults and fault zones that traverse the nearby vicinity. Several COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 10of28 of these faults, including the Rose Canyon Fault Zone, are considered active faults. Further discussion of faulting in regards to the site is discussed in the Geologic Hazards section of this report. 5.2 Site Geology Previously published geologic maps conducted by Kennedy and Tan (2008) suggest that the subject property is underlain at depth by the Santiago Formation (Tsa) and Old Paralic Deposits (Qop). Overlying the rocks is Top Soil (Qs). The Old Paralic Deposits are covered by Top Soil (Qs) along the surface of the property site as encountered in Boring Nos. I and 2 (B-I and B-2). The general geologic conditions are depicted on cross-section A-A" enclosed on Figure 3. A brief description of the earth materials encountered on the site are as follows: Top Soil (Qs) In Borehole Nos. 1 and 2 (B-I and B-2), 2.5 to 2 feet Of Top Soil was encountered, respectively. The Top Soil is a reddish dark brown, fine grained, extremely well sorted, moderately dense sand and has an organic odor. Old Paralic Deposits (Qop) Approximately 17 feet and 18 feet of Paralic sediments were encountered in Borehole Nos. I and 2 (B-i and B-2) respectively. In Borehole I, from 2.5 feet to 11.5 feet and in Borehole 2, from 2 feet to 11.5 feet, the sediments are* tan reddish brown, fine and medium grained sandstone, slightly moist and moderately dense. From 11.5 feet to 16 feet in Borehole 1 and 11.5 feet to 15 feet in Borehole 2, the sediments are light brownish tan to red brown fine- grained sandstone, well sorted, dense, slightly moist and contain rounded gray pebbles. It's important to note the gravel layer was penetrated in both boreholes at an approximate depth between 13 to 17 feet. In Borehole 1 from 16 feet to 19 feet and Borehole 2 from 15 feet to 19.5 feet, the sediments encountered were tan to light orange to red brown coarse to fine- grained sandstone, slightly moist and moderately dense. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 11 of 28 Santiago Formation (Tsa) Underlying the Old Paralic Deposits is the Santiago Formation. This formation Of interbedded sands and clays was encountered at a depth of 19 feet in Borehole 1 and 19.5 feet in Borehole 2 and extended to the maximum depths of 50 feet and 30 feet in Boreholes 1 and 2, respectively. It consists of gray to pale green to white clayey fine to coarse grained sandstone and is very dense and slightly moist. 5.3 Expansive Soil Based on our experience in the area and previous laboratory testing of selected samples, the Paralic deposits reflect an expansion potential .in the low range. 5.4 Groundwater Conditions No evidence of perched or high groundwater tables were encountered to the depth explored. However, the upper Paralic Deposits are pervious and the underlying Santiago Formation is relatively impervipus suggesting that perched groundwater conditions can develop from infiltration of water. It should be noted that seepage problems can develop after completion of construction. These seepage problems most often result from drainage alterations, landscaping, and over-irrigation. In the event that seepage or saturated ground does occur, it has been our experience that they are most effectively handled on an individual basis. 6. GEOLOGIC HAZARDS 6.1 Faulting and Seismicity The subject site is located within the seismically active Southern California region, which is generally characterized by northwest trending, right-lateral strike-slip faults and fault zones. Several of these fault segments and zones are classified as active by the California Geologic Survey (Alquist-Priolo Earthquake Fault Zoning Act.). As a result, ground shaking is a potential hazard throughout the region. COAST GEOTECHN1CAL Brett Farrow W.O. 686218 Page 12 of 28 Based on a review of published geologic maps, no known active faults traverse the. site (Figure 6). Thus, ground surface rupture is not likely to occur as a result of an earthquake or seismic event. The nearest active fault to the site is the Newport Inglewood Fault (offshore), located approximately 4.5 miles West of the site. It should be noted that the Newport Inglewood Fault is one of four-main fault strands that make up the Newport-Inglewood/Rose Canyon (NIRC) fault system (Treiman, 1984). The four strands form a series of right-stepping en echelon faults situated along the Southern California coastline. A recent study by Sahakian et al. (2017) concluded that the geometry of the NIRC fault system may enable rupture along the entire length of the fault zone. The study also modeled several rupture senaros in light of the newly defined geometry which suggest earthquake ruptures up to magnitudes (M) of 7.4 are possible along the NIRC system. While the models are intriguing, the paper recommends further research and modeling on the NIRC fault geometry to improve our understanding of potential hazards and ground shaking along the Southern California coast. Therefore, the modeled rupture magnitude of M = 7.4 on the Rose Canyon Fault was not used for the recommendations for this investigation. Other nearby faults that may affect the site include the Rose Canyon, Coronado Bahk, Temecula and Julian FaUlts. The proximity of major. faults to the site, and their estimated maximum earthquake magnitudes and peak site accelerations are enclosed on Table 1 and were determined by EQFAULT version 3.00 software (Blake, 2000). COAST GEOTECHNICAL Brett sParrow. W.G.86218 Page 13 of 28 Table 1: P!incipai Active Faults Appjoxmiate Distazfce Ma(rnum!EQ Peak ite Fault Name Newport-lnglewood. 4.5 6.9 0.388* Rose Canyon 4.8 6.9 0.381 EJsinore-Temecul. 20.9. 7.4 . 0.223 Elsinore- Julian. . . 24:1 6.8 0.152 Elsinore- Glen Ivy 24.5 7.1. 0. 1.74 Palos Verdes . 33.0 6.8 0116 Earthquake Valley. 34.9 7.1. 0.131 Newport-IngIewood' ;44.6 6.5s : 72 San Jacinto- Anza. . 45.0 6;9, O092 The.Rose Canyon Fä1Alti ôapab1ëOf geherating ä.maitüde àithquákë whiôh would cause-.strong ground motions at the subject site Further analysis on seismicity and the site specific seismic parameters. are: discussed.. in the Recommendations chapterofihis r.ep:ort. 2Ijn1sIjde Potential A landilide is the. displaemettt.. of a mass Of rock, debris, t. down: a slope, caused by tpographic, geologic al, geotechnical and/or subsurface water cpjitions. Potential laridli4 ha4s:fpr.*he sie'were:a$essedusing th.review of pub1ishd: geologic .andmpographic.:rnaps as well as substiface. explotation. According to the Landslide Hazards map, San Luis Ray Quadrangle (Tan and Giffen, 1995), the site is located within Susceptibility Area 3-I where slopes are generally susceptible MOO sl inopes this area donot contain landslide deposits, but'.they ëah be subjt to. sirflciàl failür&andbluffretreatas discussed-below. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 14 of 28 The rear bluff descends at a gradient approaching 11/4: 1 (horizontal to vertical) for approximately 40 vertical feet and is underlain by two (2) major geologic units with different characteristics. The upper 20 feet of the rear bluff is composed of Pleistocene-age sediments that are weakly cemented and friable along slope faces. These fine-grained sands are subject to surficial failures and bluff retreat. Wood bailer boards have been installed in the slope to retard surficial slippage with limited success. Underlying the coastal bluff sediments, Eocene-age sedimentary units which have commonly been correlated with the Santiago Formation are present. The sedimentary rock is primarily composed of dense to very dense clayey sandstone. Although claystone units within the Santiago Formation have been associated with landslides, no evidence of deep-seated instability was observed in the exploratory borings or site topographic expression. Slope stability analysis utilizing GSTABL7 with STEDwin suggests the most critical failure surface is primarily within the upper Pleistocene Old Paralic Deposits. Static and Pseudo-static stability analyses are shown on the enclosed Stability Analysis Appendix C. 6.3 Liquefaction Potential Liquefactionis a process by which a sand mass loses its shearing strength completely and flows. The temporary transformation of the material into a fluid mass is often associated with ground motion resulting from an earthquake, and high groundwater conditions. The fifty (50) foot deep boring (B- 1)suggests that the Paralic Deposits are in amedium-dense to dense condition and the underlying sedimentary units of the Santiago Formation are in a very dense condition. Groundwater was not encountered to a depth of 50 feet below existing ground surface. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 15 of 28 Owing to the moderately dense to very dense nature of the geologic formations and the anticipated depth to groundwater, the potential for seismically-induced liquefaction and soil instability is considered low. 6.4 Tsunami Potential Tsunamis are large sea waves generated by earthquakes, volcanic eruptions, or landslides that potentially cause the displacement of substantial volumes of water. The Tsunami Inundation Map for Emergency Planning: San Luis Ray Quadrangle (California Emergency Management Agency, 2009) suggests that the site is not susceptible to flooding from tsunamis. 7. CONCLUSIONS No geologic hazards such as faulting, liquefaction or deep-seated instability which could preclude development were encountered on the site. The rear slope is composed of friable Pleistocene sediments which are subject to erosion, surficial failure and retreat during prolonged rainfall and drainage directed toward the top of the slope. Design plans should consider raising the proposed pad grades such that drainage is directed to the south away from the top Of the bluff. The geologic conditions underlying the -rear bluff are such that infiltrated water developing saturated conditions can adversely affect slope, stability. Storm water infiltration should be significantly limited and, if necessary, bioretention basins should be located inn the most southern portion of the. site. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 16 of 28 The existing soil and weathered Paralic Deposits are not suitable for the support of proposed footings, slab-on-grade, exterior improvements or proposed fills in their present condition. These deposits should be removed and replaced as properly compacted fill. Disturbed soils resulting from the demolition of structures and utility lines should be removed and replaced as properly compacted fill. Prior to the double-ring infiltration test, the area was excavated into the Old Paralic Deposits about the 42 foot elevation. Testing in the area of the site (IF-1) was conducted in the Paralic Deposit and reflected a stabilized infiltration rate approaching that of 2.48 inches per hour. 8. RECOMMENDATIONS 8.1 Removals and Recompaction The existing soil and weathered Old Paralic Deposits in the building pad should be removed and replace as properly compacted fill. Removals in building pads should extend a minimum of 5.0 feet beyond the building footprint or the entire building pad depending upon. final design plans. The depth of removals are anticipated to be on the order of.3.O feet in building pads. Most of the existing earth deposits are generally suitable for reuse, provided they are cleared of all vegetation, debris, and thoroughly mixed. Prior to placement of fill, the base of the removal should be observed by a representative of this firm. Additional overexcavation and recommendations may be necessary at that time. The exposed bottom should be scarified to a minimum depth of 6.0 inches, moistened as required, and compacted to a minimum of 90 percent the laboratory maximum dry density. Fill should be placed in-6.0 to 8.0 inch lifts, moistened to approximately 1.0-2.0 percent above optimum moisture content and compaction to a minimum of 90 percent the laboratory maximum dry density. Soil and weathered Paralic Deposits in areas of proposed concrete flatwork, exterior improvements, and driveways should be removed and replaced as properly compacted fill. Imported fill, if necessary, should consist of non-expansive granular deposits approved by the geotechnical engineer. COAST GEOTECHNICAL Brett Farrow W.O.686218 Page 17 of 28 8.2 Temporary Slopes and Excavation Characteristics Temporary excavation, which expose soil and. weathered Paralic Deposits should be trimmed to a gradient of 1:1 (horizontal to vertical) or less depending upon conditions encountered during grading. The Old Paralic Deposits may be excavated to a vertical height of 5.0 feet. The temporary slope recommendations assume no surcharges are located or will be placed along the top of the slope within a horizontal distance equal to one half the height of the slope. The Paralic Deposits are dense below the weathered zone. However, based.on our experience in the area, the Paralic Deposits are rippable with conventional heavy moving equipment in good working order. 8.3 Foundations The following design parameters are based on footings founded into non-expansive approved compacted fill deposits or competent Paralic Deposits. Footings for the proposed structure should be a minimum of 12 inches and 15 inches wide and founded. a minimum of 12 inches and 18 inches below the lower most adjacent subgrade at the time offoundation construction for single-story and two-story structures, respectively. A 12 inch by 12 inch grade beam or footing. should be placed across the garage opening. Footings should be reinforced with a minimum of four No.4 bars, two along the top of the footing and two along the base. Where parallel wall footings occur, the upper footing should be deepened belOw a 45 degree plane projected up from the base of the lower footing, or the lower wall should be designed for the additional surcharge load from the upper wall. Footing recommendations provided herein are based upon underlying soil conditions and are not intended to be in lieu of the project structural engineer's design. The base of footings should be maintained a minimum horizontal distance of 10 lateral feet to the face of the nearest slope. For design purposes, an allowable bearing value of 2000 pounds per square foot and 2400 pounds per square foot may be used for foundations at the recommended footing depths for single and two story structures, respectively. COAST GEOTECH14ICAL Brett Farrow W.O. 686218 Page 18 of 28 For .footings deeper than 18 inches, the bearing value may be increased by 250 pounds per square foot for each additional 6.0 inches of embedment to a maximum of 3000 pounds per square foot. The bearing value maybe increased by one-third for the short durations of loading, which includes the effects of wind and seismic forces. The bearing value indicated above is for the total dead and frequently applied live loads. This value may be increased by 33 percent for short durations of loading, including the effects of wind and seismic forces. 8.4 Sulfate and Chloride Tests The results of our sulfate and chloride tests performed on representative samples are presented on Tables 8 and 9 in Appendix B. The test results suggest a sulfate content of 0.005 (negligible). 8.5 Slabs on Grade (Interior and Exterior) Slab on grade should be a minimum of 5.0 inches thick and reinforced in both directions with No. 3 bars placed 18 inches on center in both directions. Exterior slabs on grade should be a minimum of 4.5 inches thick-and reinforced with No. 3 placed 18 inches on center in both directions. The slab should be underlain by a minimum 2.0-inch coarse sand blanket (S.E. greater than 30). Where moisture sensitive floors are used, a minimum 10.0-mil Visqueen, Stego, or equivalent moisture barrier should be placed over the sand blanket and covered by an additional two inches of sand (S.E. greater than 30). Utility trenches underlying the slab may be backfilled with on-site materials, compacted to a minimum of 90 percent of the laboratory maximum dry density. Slabs should be reinforced as indicated above the provided with saw cuts/expansion joints, as recommended by the project structural engineer. All slabs should be cast over dense compacted subgrades. At a minimum, interior slabs should be provided with soficut contraction/control joints consisting of sawcuts spaced 10 feet on center maximum each way. Cut as soon as the slab will support the weight of the saw, and operate without disturbing the final finish, which is normally within 2 hours after final finish at each control joint location or 150 psi to 800 psi. The soficuts should be a COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 19 of 29 minimum of 3/4 inch in depth, but should not exceed 1 inch deep maximum. Anti-ravel skid plates should be used and replaced with each blade to avoid spalling and raveling. Avoid wheeled equipment across cuts for at least 24 hours. Provide re-entrant corner (270 degrees corners) reinforced for all interior slabs consisting of minimum two, 10-feet long No. 3 bars at 12 inches on center with the first bat placed 3 inches from re-entrant corner (see Plate F). Re-entrant corners will depend on slab geometry and/or interior column locations. Exterior slabs should be provided with weakened planejoints at frequent intervals in accordance with the American Concrete Institute (ACI) guidelines. Our experience indicates that the use of reinforcement in slabs. and foundations can reduce the potential for drying and shrinkage cracking. However, some minor cracking is considered normal and should be expected as the concrete cures. Moisture barriers can retard, but not eliminate moisture vapor movement from the underlying soils up through the slab. 8.6 Lateral Resistance Resistance to 1ateral load may be provided by friction acting at the base foundations and by passive earth pressure. A coefficient of friction of 0.25 may be used with dead-load forces. Design passive earth resistance may be calculated from a lateral pressure corresponding to an equivalent fluid density of 300 pounds per cubic foot with a maximum of 2500 pounds per square foot. 8.7 Retaining Walls Cantilever walls (yielding) retaining nonexpansive granular soils may be designed for an active-equivalent fluid pressure of 37 pounds per cubic foot for a level surcharge and 45 pounds per cubic foot for a sloping backfill.. Restrained walls (nonylelding) should be designed for an "at-rest" equivalent fluid pressure of 60 pounds per cubic foot. Wall footings should be designed in accordance with the foundation design recommendations. All retaining walls should be provided with adequate backdrainage system. A geocomposite blanket drain such as Miradrain 6000 or equivalent is recommended behind walls. The soil parameters assume a level nonexpansive select granular backfill compacted to a minimum of 90 percent of the laboratory maximum dry density. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 20 of 28 & 8 Dynamic (Seismic) Lateral Earth Pressures For proposed restrained walls (non-yielding), potential seismic loading should be considered. For smooth rigid walls, Wood (1973) expressed the dynamic thrust in the following form: LWe = kh?H2 (nonyielding) where kh is peak ground acceleration equal to 50 percent of the design spectral response acceleration coefficient (Sds) divided by 2.5 per C.B.C. (2007), y is. equal to the unit weight of backfill, and H is equal to the height of the wall. The pressure diagram for this dynamic component can be approximated as an inverted trapezoid with stress decreasing with. depth. The point of application of the dynamic thrust is at a height of .0.6 above the base of the wall. The magnitude of the resultant is: AN = 20.3 H2 (nonyielding) This dynamic compOnent should be added to. the at-rest static pressure for seismic loading conditions. For cantilever walls (yielding), Seed and Whitman (1970) developed the dynamic thrust as: AN = 3/8 kbyH2(yie1ding) COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 21 of 28 The pressure diagram for this dynamic component can be approximated as an inverted trapezoid with stress decreasing with depth and the resultant at a height of 0.6 above the base of the wall. The magnitude of the resultant is: AN = 7.62 H2 (yielding) This dynamic component should be added to the static pressure for seismic loading conditions. 8.9 Settlement Characteristics Estimated total and differential settlement over a horizontal distance of 30 feet is expected to be on the order of 1.0 inch and 3h inch, respectively. It should also be noted that long term secondary settlement due to irrigation and loads imposed by structures is anticipated to be /4 inch. & 10 Seismic Considerations Although the likelihood of ground rupture on the site is remote, the property will be exposed to moderate to..high levels- of ground motion resulting from the release of energy should an earthquake occur along the numerous known and unknown faults in the region.. The Newport-Inglewood (offshore) Fault Zone located approximately 4.5 miles west of the property is the nearest known active fault, and is considered the design fault for the site. In addition to the Newport-Inglewood fault, several other active faults may affect the subject site. Seismic design parameters were determined as.part of this investigatiOn in accordance with Chapter 16, Section 1.613 of the 2016 California Building Code (CBC) and ASCE 7-10 Standard using the web-based United States Geological Survey (USGS). Seismic Design Tool. The generated results for the parameters are presented on Table 2. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 22 of 28 Table 2: Seismic Design Parameters Factôis Site Class D Seismic Design Category 1/11/Ill Site Coefficient, Fa 1.037 Site Coefficient, F 1.556 Mapped Short Period Spectral Acceleration, S 1.158 Mapped One-Period Spectral Acceleration, S1 0.444 Short Period Spectral Acceleration Adjusted for Site Class, SMS 1.201 g One-Second Period Spectral Acceleration Adjusted for Site, SMI 0.691 g Design Short Period Spectral Acceleration, SOS 0.800 g Design One-Second Period Spectral Acceleration, 5D1 0.461 g & 11 Preliminary Pavement Design The following preliminary pavement section is recommended for proposed driveways: 4.0 inches of asphaltic concrete on 6.0 inches of select base (Class 2) on 12 inches of compacted subgrade soils or 5.5 inches of concrete on 12 inches of compacted subgrade soils Subgrade soils should be compacted to the thickness indicated in the structural section and left in a condition to receive base materials. Class 2 base materials should have a.minimurn R-value of 78 and a minimum sand equivalent of 30. Subgrade soils and base materials should be compacted to a minimum of 95 percent of their laboratory maximum dry density. Concrete should be reinforced with No. 3 bars placed 18 inches on center in both.directions. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 23 of 28 The pavement section should be protected from water sources. Migration.of water into subgrade deposits and base materials could result in pavement failure. 8.12 Permeable Interlocking Concrete Payers (PICP) Permeable Interlocking Concrete Payers (PICP), if proposed, should consider several design aspects. Foundations adjacent to or in close proximity to PICP should be protected by an impervious membrane extending a minimum of 3.0 lateral feet from the foundation under the pavement section. The intent is to reduce lateral migration of infiltrated drainage and potential impact on footings. However, this approach is considered less desirable from a geotechnical viewpoint than lining the entire section with an impervious liner. Pavement underdrains are recommended and should be incorporated in the design for proper collection and disposal of filtrated storm water as indicated on Plate G. If subdrains are not allowed for storm water infiltration by reviewing agencies, the long term effects of infiltrated water on structural foundations and slabs cannot be predicted with any degree of certainty, PICP pavement structural section (Driveways) should consist of 31/e inch .PICP, over a minimum of 2.0 inches of ASTM No. 8. bedding course/choke stone, over a minimum of 8.0 inches ofASTM No. 57 stone base course, over a minimum of 12 inches of 95 percent compacted subgrade. Bedding course/choke stone and base course stone should also be well compacted, consolidated, and interlocked. (avoid crushing the underdrain pipes) with heavy construction equipment. ASTM No. 8, No. 9 or No. 89 should be used for joint materials, depending on the joint size and per manufacturer recommendations. The above stone base section may be reduced from 12 inches to a minimum of 6.0 inches for walkways and patios, if desired. The gradational requirements are. summarized on Table 3. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 24 of 28 Table 3: Gradational Requirements for ASMT No. 57, No. 8, No. 89, and No. 9 Sieve Size Percent Passing No. 57 No.-8 No. 89 No. 9 1V2 100 -- -- -- In 95to100 -- -- -- 'A" 25 to 60 100 100 -- -- 85 to 100 90 to 100 100 No.4 OtolO 10to30 20to55 85to.100 No.8 0to5 OtolO 5to30 10to40 No. 16 -- 0to5 OtolO O to. lO No. 50 -- -- 0to5 0to5 8.13 Utility Trench We recommend that all utilities be bedded in clean sand to at least one foot above the top of the conduit. The bedding should be flooded in place to fill all the voids around the conduit. Imported or on-site granular material compacted to at least 90 percent relative compaction may be utilized for backfill above the bedding. The invert, of subsurface utility excavations paralleling footings should be located above the zone of influence of these adjacent footings. This zone of influence is defined as the area below a 45 degree plane projected down from the nearest bottom edge of an adjacent footing. This can be accomplished by either deepening the footing, raising the invert elevation of the utility, or moving the utility or the footing away from one another. 8.14 Drainage Specific drainage patterns should be designated by the project architect or engineer. However, in general, pad water should be directed away from foundations and around the structure to the street. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 25 of 28 Roof water should be collected and conducted to the. street via non-erodible devices. Pad water should not be allowed to pond. Vegetation adjacent to foundations should be avoided. If vegetation in these areas is desired, sealed planter boxes or drought resistant plants should be considered. Other alternative may be available, however, the intent is to reduce moisture from migrating. into foundation subsoils. Irrigation should be limited to that amount necessary to sustain plant life. All drainage systems should be inspected and cleaned annually, prior to winter rains. & 15 Geotechnical Observations Structural footing excavations should be observed by a. representative of this firm prior to the placement of steel and forms. All fill should be placed while a representative of the geotechnical engineering is presentto observe and test. 8.16 Plan Review A copy of the final plans should be submitted to this office for review prior to the initiation of constructions. Additional recommendations may be necessary at that time. 9. LIMITATIONS This.report is presented with the provision that it is the responsibility of the owner or the owner's representative to bring the information and recommendations given herein to the attention of the project's architects and/or engineers so that they may be incorporated into the plans. If conditions encountered during construction appear to differ from those described in this report, our office should be notified so that we may consider whether modifications are needed. No responsibility for construction compliance with design concepts, specifications, or recommendations given in this report is assumed unless on-site review is performed during the course of construction. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 26 of 28 The subsurface conditions, excavation characteristics, and geologic structure described herein are based on. individual exploratory excavations made on the subject property. The subsurface conditions, excavation characteristics, and geologic structures discussed should in no way be construed to reflect any variations which may occur among the exploratory excavations Please note that fluctuations in the level of groundwater may occur due. to variations in rainfall, temperature, and other factors-not evident at the time measurements were made and reported herein. Coast Geotechnical assumes no responsibility for variations which may occur across the site. The conclusions and recommendations of this report apply as of the current date. In time, however, changes can occur on a property whether caused by acts of man or nature on this or adjoining properties. Additionally, changes in professional standards may be brought about by legislation or the expansion of knowledge. Consequently, the conclusions and recommendations of this report may be rendered wholly or partially invalid by event beyond our control. This report is therefore subject to review and should not be relied upon after the passage of two years. The professional judgements presented herein are founded partly on our-assessment of the technical data gathered, partly on our understanding of the proposed construction, and partly on our general experience in the geotechnical field. However, in no respect do we guarantee the outcome of the project. This study has been provided solely for the benefit of the client, and is in no way intended to benefit or extend any right or interest to any third party. This report is not to be used on other projects or extensions to this project, except by agreement in writing with Coast Geotechnical. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 27 of 28 REFERENCES Blake, T. F. (2000). EQFAULT: A Computer Program for the Deterministic Estimation of Peak Acceleration using Three-Dimensional California Faults as Earthquake Sources, Version 3.0, Thomas F. Blake Computer Services and Software, Thousand Oaks, CA. California Building Standards Commission. (January 1, 2016). 2016 California Building Code, California Code of Regulations. California Emergency Management Agency, California Geological Survey, and University of Southern California. (2009). Tsunami Inundation Map for Emergency Planning- San Luis Rey Quadiangle, California, San Diego County, Scale. 1:24,000. California Geologic Survey, (1994), Fault Activity Map of California, Map Scale 1=75O,00'. Gregory Geotechnical Software; GSTABL7 with STEDwhi (1996, 1999). Slope Stability Analysis System. Kennedy, M. P., and Tan, S. S. (2008). California Geological Survey, Regional Geologic Map No. 3,.1:100,000 scale. Sahakian, V., et al. (2017). Seismic Constraints on the Architecture of the Newport-Inglewood/Rose Canyon Fault: Implications for the Length and Magnitude of Future Earthquake Ruptures. American Geophysical Union. DO!: 10.1002/2016JB0 13467. Sampo Engineering Inc. (2018). Topographic Plat: 570-580 Laguna Drive, Carlsbad, California, Scale I"= 20'. COAST GEOTECHNICAL Brett Farrow W.O. 686218 Page 28 of 28 REFERENCES (CONT.). Seed, H.B., and Whitman, R.V. (1970). Design of earth retaining structures for dynamic loads. In Proceedings of the ASCE.SpeciaiCorference on Lateral Stresses, Ground Disp1aemnt and Earth Retaining Structure, Ithaca, N.Y., pp. 103-147. Tan, S. S., and Giffen, D. G. (1995). Landslide Hazards in the Northern Part of the San Diego Metropolitan Area, San Diego Countyj California, OFR 95-04, Plate 35D. Treiman, J. A. (1984). The Rose Canyon Fault Zone: A Review and Analysis, California Division of Mines and Geology, Fault Evaluation 'Report 216. Wood, J.H. (1973). Earthquake-induced soil pressures on structures. Ph.D. thesis, the California Institute of Technology, Pasadena, Calififornia. USGS, U. S. Seismic. Design Naps, Scale = Variable: https://earthquake.usgs.gov/dësignmaps/us/application.php APPENDIX A COAST GEOTECIINICAL 5931 Sea Lion Place, Suite 109 Carlsbad, CA 92010 570-580 Laguna Drive Carlsbad, CA 92008 Figure 1 P-686218 APPENDIX B LABORATORY TESTING AND RESULTS Earth materials encountered in the exploratory trenches were closely examined and sampled for laboratory testing. The laboratory tests were performed in accordance with the generally accepted American Society for Testing and Materials (ASTM) test methods or suggested procedures. Classification: The field classification was verified through laboratory examination, in accordance with the Unified Soil Classification System. The final classification is shown on the enclosed Exploratory Logs provided in Appendix B. Grain Size Distribution: The grain size distribution of selected soil samples was determined in accordance with ASTM D6913-04. The test result is presented on Table 4 and is graphically depicted on the following pages. TABLE 4 Sieve Size ijil f 3/4 92'r' #' #10 #26 140 1O0 #200 Location Soil Type . Percentage Passing B1@5' 1 100 100 100 100 199.9 198.8 186.3 139•9 I28.4 Expansion Index Test: An Expansion Test was performed on the selected sample. The test procedure were conducted in accordance with the Uniform Building Code, Standard No. 29-2 and AMST D-4829. The classification of expansive soil, based on the expansion index, are as indicated in Table•29-C of the Uniform Building Code. The test result is presented on Table 5. Location Soil Type Expansion Reading Degree of Saturation Uncorrected 'Expansion Index (El) Corrected El for 500/o Saturation B1@l-5' 1 -0.01 38.6Sm N/A N/A Maximum Dry Density and Optimum Moisture Content: The maximum dry density and optimum moisture content were determined for selected samples of earth materials taken from the site. The laboratory standard tests were in accordance with AS1'M D- 1557-12. The test result is presented on Table 6. TABLE 6 Maximum Dry Optimum Moisture Location Soil Type ensity (ym-pcf) Content (copt-%) Bi @ 11-5' 1 130.0 9.0 Moisture/Density: The field moisture content and dry unit weight were determined for each of the undisturbed soil samples. Test procedures were conducted in accordance with ASTM D7263-09 (Method A). Thi information is useful in providing, a gross picture of the soil consistency or variation among exploratory excavation. The field moisture content was determined as a percentage of the dry unit weight. The dry unit weight was determined in pounds per cubic foot (pcf). The test results are presented on Table 7. TABLE 7 Sample Location Soil Type Field Moisture Coiileiit.%) Field Dry Density ydpcf Max Dry -Density yrn-pcf In-p1ace..Re1ätive Compaction (%) Degree of Saturation (%) 1@3.5' 1 2.6 117.0 130 90.0 15.3 1@9' 2 2.2 109.7 130 84.4 10.7 1@14' 2 6.5 110.0 130 84.6 31.9 1@19' 3 8.9 122.1 - - - l@30' 3 9.2 118.6 - - - 1@39' 3 8.3 88.1 - - - 2@4' 1 8.5 126.4 130 97.2 65.2 2@9' 2 6.5 104.2 130 80.2 27.6 2@19' 3 6.7 106.6 - - - ShearTest: Shear tests were performed in a strain-control type direct shear machine. The laboratory standard tests were in accordance with ASTM D3080. The rate of deformation was approximately 0.025 inches per minute. Each sample was sheared under varying confining loads in order to determine the Coulomb shear strength parameters, cohesion, and angle of internal friction. Samples were tested in a saturated condition. The test results are presented in Table 8. TABLE 8 Sajnple ID Angle of Internal Friction Apparent Cohesion B-I @ 9' (ring) 29 degrees 70 psf B-1 @ 30' (ring) 34 degrees 350 psf Sulfate and Chloride Tests: A sulfate test was performed on a selected sample in accordance with California Test Method (CTM) 417, and a chloride test was performed on a selected sample in accordance with California Test Method (CTM) 422. The test results are presented on Tables 9 and 10. TABLE 9 Sample ID Sulfate Câñteñt (ppih) Sulfate Content (% by wgt) B-i @ 1-5 48 0.005 TABLE 10 Sample ID Chloride Content (ppm) Chloride Content (% by wgt) B-I @ IS 21 0.002 Infiltration Testing: Infiltration tests were performed in accordance to A.STM D3385-09. This test method is useful for field -measurement of the infiltration rate of soils. A stabilized infiltration rate of 2.48 inches per hour was established. The results of our testing are graphically shown on Figure 7. The rates indicated above are actual rates measured in the field and do not include asafety factor. An adequate safety factor as recommended by the project engineer should be incorporated. Field &Resistivity Test:: Afield resistivity.test wasprfármed on a selected sample inaccordance.with Califàrnia Test:Method (CTM).6 3.. The fleld reiti.ity test gives an indication of the quantity of soliible.salts in the SoiLór Wàterto obtain data estimating the service life ofcuiverts. The test resUlts for pH and field.reals&ity are presented. on .lable'l I PH: 7.6 - Watcr AdJed tnf) Rcsisti a obn-cm 10 . 13000 5 7800 5 . . 6700 5 . . :• 5600 S. . . ., 5500 5200. 5 5900 :60-y to perforation of a 16 gauge metal culvert 78 years to perforation of a 14 gauge metal culvert 108 years to pibration of a 12 gauge metal culvert 138 years to perforation of 4. 10 gauge metal culvert. 168 years to perforation of a 8 gauge metal culvert. Accum. Wt. (gr) 0.1 0.8 6.6 77.4 338.4 403.6 409.5 % Passing 100.0 99.9 98.8 86.3 39.9 28.4 % Retained 0.0 0.1 1.0 12.6 46.3 11.6 1.0 SMS Geotechnical Solutions, Inc. Sieve Analysis 5931 Sea Lion place, Suite 109 ASTM D6913-04 Carlsbad, CA 92010 Sample 1 Project Farrow Job U 686218 I Supervising Lab Tech SIB Sample Bi @ 1-5' Soil type [ 1 Supervising Lab Manager MS Date Tech F WB Address I 578 Laguna Drive I Sample Wet Wt. I 584.6 gr Sample Dry Wt. 1 563.5 gr I Moisture % 3.7 I Seive 152 mm 6' 75 mm 3" 50 mm 2" 37.5 mm 11/2" 25 mm 1" 19 mm 3/4" 12.5 mm 1/2" 9.5 mm 3/8" 4.75 mm #4 2mm #10 0.85 mm #20 0.6 mm #30 0.425 mm #40 0.15 mm #100 0.075 mm! #200 Pan Specification D.G. Class 2 100 100 90-100 100 87-100 50-100 30-65 25-55 5-35 5-18 0-12 DOUBLE RING L\BLTROME1IR TEST DATA ft~ect Nsme and 'flat Location: Constents- Rina - Data MarrioteTubes Lagoon IF-1 AU. .1., Dtb of I_iquad (in) Small Large (cc) DPI Factor EMU RZnE 113.1 6.00' 3,000 cc 104V-S.352cc' ThtBy juscsciawj - .&m!vhrSpe: 3393 6.25" 10,000 CC lDN&S3ccI %VatuTabItD~l Inerl - 2.5 OUter 2.5 DteofT 3/19/18IL4%i4J9H2O. I pfl4 e undThnp(f) atDepd () Flow Vi1v( Float D ManiotteTub. ( )Other .Mditiona1Cosfs I Vol cm2x 0.061 =Voc in3 Qf= (DlV) x DIV FACTOR x 0.061= In3 Time tnter9 lime (himm) Di (itin) & Tote lnnerRini Ainni1uj Liqnid Temp Infi1traüonRaej Remadcs : . inner inbr Outet ial I -Stan 12.23 14 0 360 0 310 66.0 4.51 4.06 - -End 12:37 (14) 360 117.52 3 2 - Start 12:45 15 0 460 0 280 5.31 3.37 End 1:00 (15) 460 150.17 280 2864 3 . Stag 103 15 0 220 0 240 2.54 2.89 End 1:18 (15) 220 71 .JL. 245.26 - 4-Sleet 1:20 iS 0 165 0 _270 1.90 3.25 End 135 - (15) 165 53.86 ... 275.92 ) - Stan 1:38 15 1 0 210 0 225 2.42 2.71 End 153 (15) 210 68.55 225 229.93 555 6- Start 137 15 0 215 0 250 2.48 3.01 -. End 2:12 (15) 215 70.1 250 255.48 SMt 2:13 15 0 225 0 210 2.59 2.53 214.60 A L 2:28 (15) 25 73.45 210 S-Stan 233 15 0 235 0 250 2.92 3.01 End 2.48 (15) 35 82.59 250 255.48 9-Start - End 10. Statt End _______ FAd- 12-Stat End 13-Start - End_______ End Figure 7 ag Design Maps Summary Report User—Specified Input Report Title Laguna Fri March 2, 2018 22:32:56 UTC Building Code Reference Document ASCE 7-10 Standard (which utilizes USGS hazard data available in 2008) Site Coordinates 33.16541°N, 117.35211W Site Soil Classification Site Class D - "Stiff Soil" Risk Category 1/11/111 ) Oc"an -. USGS—Provided Output Ss = 1.158 g SMS = 1.201 g S's = 0.800 g S1 = 0.444 g Sm, = 0.691 g S01 = 0.461 g For information on how the SS and Si values above have been calculated from probabilistic (risk-targeted) and deterministic ground motions in the direction of maximum horizontal response, please return to the application and select the "2009 NEHRP" building code reference document. MCP. Sruc'j'n Des 'co1sc ScYrn For PGAM, TL, C, and C 1 values, please view th..dti1d reoort. Although this information is a product of the U.S. Geological Survey, we provide no warranty, expressed or implied, as to the accuracy of the data contained therein. This tool is not a substitute for technical subject-matter knowledge. ZUSGS Design Maps Detailed Report ASCE 7-10 Standard (33.165410N, 117.352°W) Site Class D - "Stiff Soil'ç Risk Category 1/11/111 Section 11.4.1 - Mapped Acceleration Parameters Note: Ground motion values provided below are for the direction of maximum horizontal spectral response acceleration. They h.ae been converted from corresponding geometric mean ground motions computed by the USGS by applying factors of 1.1 (toobtan S) and 1.3 (to obtain S1). Maps in the 2010 ASCE-7 Standard are provided for Site Class B. Adjustments for other Site Classes. are made; as needed, in Section 11.4.3. From Figure 22-4 (1) S5 = 1.158:g From Figure 22-2 (2) S1 = 0.444 Section 11.4.2 - Site Class The authority having jurisdiction (not the. USGS), site-specific geotechnical data, and/or the default has classified the site as Site Class D, based on the site soil properties in accordance with Chapter 20.. Table 20.3-1 Site Classification Siti Class, .VS N or Pith su A. Hard Rock >5,000 ft/s N/A N/A B._Rock 2,500 to 5,000 ft/s N/A N/A C.. Very dense soil and soft rock 1,200 to 2,500 ft/s >50 >2,000-psf .D. Stiff Soil 600th 1,200 ft/s 15 to 50 . 1,000 to 2,000 psf - E. SOft clay soil <600 ft/s <15 <1,000 psf Any profile with more than 10 ft of soil having the chaacteristics: Plasticity index P1 20, Molsture'.cortent w ~_* 40%, and Undrained shear strength; <5Ô0 psf F. Soils requiring site response See Section 20.3.1 analysis In accordance with Section 21.1 For SI: Ut/s = 0.3048 rn/s 1ib/ft2 = 60479.kN/m2 Section 11.4.3 - Site Coefficients. and Risk-Targeted Maximum Considered Earthquake(g) Spectral Response Acceleration Parameters Table 11.4-1: Site Coefficient F1 Site Class Mapped MCE a Spectral Response Acceleration Parameter at Short Period S5 :50.25 S5 = 0.50 55 = 0.75 55 = 1.00 S ~:1.25 A 0.8 0.8 0.8 0.8 0.8 B 1.0 1.0 1.0 1.0 1.0 1.1 E E 1.2 E ' E E F See SectiOn 11.47ofASCE7 Note: Use straight-line interpolation for* intermediate values of S ForSite Class = D and S5 = 1.158 g, F. = 1.037 Tab!è 11.4-2: Site Coefficient .F, Site Class Mapped MCE R Spectral Response Acceleration Parameter at 1-s Period S1 50.10 S1 = 0.20 S = 6.30 S1 =0.40 S1 0.50 A 0.8 0.8 0.8 0.8 0.8 B 1.0 1.0 1.0 1.0 1.0 E 1.5 E. ' E E F See Section 11.4.7 of ASCE 7 Note: Use straight-line interpolation for intermediae values of S For Site Class '= D and S = 0.444 g, F. =1.556 Equation (11.4-1): SMS = FaSs = 1.037 X 1.158 = 1.201 g Equation (11.4-2): SMI = FS1 = 1.556 x 0.444 = 0.691 g Section 11.4.4 - Design, Spectral Acceleration Parameters Equation (11.4-3): S0 = % Sms = Wx. 1.201 = 0.800 g Equation (11.4-4): S01 = =2/3 x ' 0.691 = 0.461 g Section 11.4.5 - Design Response Spectrum From Figure 2242131 TL = 8 seconds Figure 11.4-1: Design Response Spectrum T 0:SS(O.4+06'T'/T0). - To S T:5T8:SS T5.cT : S= S/T \ : S. .SmTL I I: I I I -I------------------------ : ' •' I I P,o& raa) r (c) - 1.2n. Section 11.4.6 - Risk-Tárgèted Maximum Considered Earthquake (MCER) Response Spectrum The MCER Response* Spectrum is determined by multiplying the design response spectrum above by 1.5. Section 11.8.3 - Additional .Geotechnical Investigation Report Requirements for Seismic Design Categories D through F From Figure 22-7 PGA = 0.46.0 Equation (11.8-11): PGAM = FPGAPGA = 1.040 x 0.460 = 0.478 g Table 11.8-1: Site Coefficient FPGA Site Mapped MCE Geometric Mean Peak Ground Acceleration, PGA Class PG S A :5 PGA = . PGA = PGA = PGA ~ 0.10 0.20 0.30 0.40 0.50 0.8. 0.8 0.8 0.8 0.8 B 1.0 1.0 1.0 1.0 1.0 1.2 E E F SeeSection 1.4.7of ASCE 7 Note; Use straight-line interpolation for Intermediate values, of PGA For Site Class = D and PGA.= 0.460 g,.F. = 1.040 $ection 21.2.1.1 - Method 1 (from Chapter 21 - Site-Specific Ground Motion Procedures for Seismic Design) From Figure 22-17 151 CRs.= 0.940 From Figure CR1 0.991 Section 11.6 - Seismic Design Category Table 11.6-1 Seismic Design Cateaory Based on Short Period Response Acceleration Parameter VALUE OF SOS RISK CATEGORY lorli III IV S05 < 0.167g A A A 0.167g' 905 < 0.33g B B C 0.33gS05 <0.509 C C D 0.509S0S D D D For Risk Category' = I and 56s = 0.800 g, Seismic Design Category' D Table 11.6-2 Seismic Design Category Based on 1-S Period Response Acceleration Parameter VALUE OF S01 RISK CATEGORY lorli III IV SDI < 0.067g A A A 0.0679 S01 < 0.133g B B C 0.1339 S S01 < 0.20g C C D O.20gSDI D D D For Risk Category = I and 501 = 0.461 g, Seismic Design Category = D Note: When S1 Is 'greater than or equal to 0.75g, 'the Seismic Design Category is E for buildings in Risk Categories I, II, and III, and F for those in Risk Category IV, irrespective of the above. Seismic Design Category "the more severe design category in accordance with Table 11.6-1 or 11.6-2" = D Note: See Section 11.6 for alternative approaches to calculating Seismic Design Category. References Figure 22-1: https ://earthquake.usgs.góv/hazards/deslg nmaps/downlbads/ pdfs/2010_ASCE-7_Flgure_22- 1. pdf Figure 22-2: https ://earthquake.usgs;gov/hazards/deslgnmaps/downloads/pdfs/20 10_ASCE-7_Figure_22-2. pdf Figure 22-12: https://earthquake.usgs.gov/hazards/desIgnmaps/downloads/pdfs/2O10_ASCE- 7_Figure_22- 12.pdf Figure 22-7 https://earthquake.usgs.gov/hazards/designmaps/downloads/pdfs/2010_ASCE-7_Figure_227.pdf Figure 22-17: https://earthquake.usgs.gov/hazards/designmaps/downloads/pdfs/2010_ASCE- 7_Figure_22-17.pdf Figure 22-18: https ://earthquake.usgs.gov/hazards/deslgnmaps/downloads/pdfs/ 20 10_ASCE- 7_Figure_22- 18.pdf APPENDIX C C:\stedwin\p-686218.OUT Page 1 ** GSTABL7 *** ** GSTABL7 by Garry H. Gregory, P.S. ** Original Version 1.0, January 1996; Current Version 2.0, September 2001 (All Rights Reserved-Unauthorized Use Prohibited) SLOPE STABILITY ANALYSIS SYSTEM Modified Bishop, Simplified Janbu, or GLE Method of Slices. (Includes Spencer & Morgenstern-Price Type Analysis) Including Pier/Pile, Reinforcement, Soil Nail, Tieback, Nonlinear Undrained Shear Strength, Curved Phi Envelope, Anisotropic Soil, Fiber-Reinforced Soil, Boundary Loads, Water Surfaces, Pseudo-Static Earthquake, and Applied Force Options. * * * * * * * * * * * * * * * * * * * * * k * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * + * * * * * * * * * * * ** * * * * * Analysis Run Date: 4/3/2018 Tine of Run: 6:09PM Run By: NB/VS Input Data Filename: C:p-686218. Output Filename: C:p-686218.OUT Unit System: English Plotted Output Filename: C:p-686218.PLT PROBLEM DESCRIPTION: LAGOON P-686218 BOUNDARY COORDINATES 9 Top Boundaries 9 Total Boundaries Boundary X-Left Y-Left X-Right Y-Right Soil Type No. (ft) (ft) (ft) (ft) Below Bnd 1 0.00 25.00 5.00 25.00 2 2 5.00 25.00 11.00 30.00 2 3 11.00 30.00 27.00 40.00 2 1 27.00 40.00 40.00 50.00 1 5 40.00 50.00 57.00 60.00 1 6 57.00 60.00 70.00 62.00 1 7 70.00 62.00 100.00 63.00 1 8 100.60 63.00 136.00 63.00 1 9 136.00 63.00 182.00 64.00 1 ISOTROPIC SOIL PARAMETERS 2 Type(s) of Soil Soil Total Saturated Cohesion Friction Pore Pressure Piez. Type Unit Wt. Unit Wt. Intercept Angle Pressure Constant Surface No. (pcf) (pcf) (psf) (deg) Param. (psf) No. 1 116.0 122.0 70.0 29.0 0.00 0.0 0 2 120.0 128.0 350.0 34.0 0.00 0.0 0 A Critical Failure Surface Searching Method, Using A Random Technique For Generating Circular Surfaces, Has Been Specified. 1250 Trial Surfaces Have Been Generated. 25 Surfaces Initiate From Each. Of 50 Points Equally Spaced Along The Ground Surface Between X = 28.00(ft) and X = 45.00(ft) Each Surface Terminates Between X = 70.00(ft) and X = 110.00(ft) Unless Further Limitations Were Imposed, The Minimum E].évation At Which A Surface Extends Is Y = D.00(ft) 5.00(ft) Line Segments Define Each Trial Failure Surface. Following Are Displayed The Ten Most Critical Of The Trial Failure Surfaces Evaluated. They Are Ordered - Most Critical First. * * Safety Factors Are Calculated By The Modified Bishop Method * * Total Number, of Trial Surfaces Evaluated = 1250 Statistical Data On All Valid FS Values: FS Max = 8.025 FS Min = 1.513 2'S Ave = 3.582 Standard Deviation = 1.278 Coefficient of Variation. = 35.68 Failure Surface Specified By 11 Coordinate Points Point X-Surf Y-Surf No. (ft) (ft) 1 29.39 41.84 2 34.14 43.38 C:\stedwin\p-686218.OUT Page 2 3 38.85 45.08 4 43.49 46.94 5 48.06 48.96 6 52.56 51.13 7 56.99 53.46 8 61.34 55.93 9 65.60 58.54 10 69.77 61.30 11 70.78 62.03 Circle Center At X = -13.8 ; Y = 183.0 and Radius, 147.6 Factor of Safety *** 1.513 *** Individual data on the 13 slices Water Water Tie Tie Earthquake. Force Force Force Force Force Surchatge Slice Width Weight Top Bot Norm Tan Mor Ver Load No. (ft) (lbs) (lbs) (lbs) (lbs) (lbs) (lbs) (lbs) (lbs) 1 4.8 583.6 0.0 0.0 0.0. 0.0 0.0 0.0 0.0 2 4.7 1675.3 0.0 0.0 0.0 0.0 0.0 0.0 0.0 3 1.2 568.1 0.0 0.0 0.0 0.0 0.0 0.0 0.0 4 3.5 1932.8 0.0 0.0 0.0 0.0 0.0 0.0 0.0 5 4.6 2888.5 0.0 0.0 0.0 0.0 0.0 0.0 0.0 6 4.5 3144.6 0.0 0.0 0.0 0.0 0.0 0.0 0.0 7 4.4 3286.6 0.0 0.0 0.0 0.0 0.0 0.0 0.0 8 0.0 5.6 0.0 0.0 0.0 0.0 0.0 0.0 0.0 9 4.3 2839.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 10 4.3 1858.1 0.0 0.0 0.0 0.0 0.0 0.0 0.0 11 4.2 831.7 0.0 0.0 0.0 0.0 0.0 0.0 0.0 12 0.2 16.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 13 0.8 24.2 0.0 0.0 0.0 0.0 0.0 0.0 0.0 Failure Surface Specified By 11 Coordinate Points Point X-Surf Y-Surf No. (ft) (ft) 1 28.00 40.77 2 32.68 42.52 3 37.33 44.38 4 41.93 46.33 5 46.49 48.38 6 51.00 50.54 7 55.47 52.78 8 59.88 55.13 9 64.25 57.57 10 68.56 60.10 11 71.73 62.06 Circle Center At X = -50.8 ; Y = 258.3 and Radius, 231.4 Factor of Safety *** 1.520 Failure Surface Specified By 12 Coordinate Points Point X-Surf Y-Surf No. (ft) (ft) 1 28.69 41.30 2 33.66 41.88 3 38.57 4.2.81 4 43.41 44.07 5 48.15 45.67 6 52.77 47.59 7 57.24 49.83 8 61.54 52.37 9 65.66 .55.21 10 69.57 58.33 11 73.25 61.71 12 73.64 62.12 Circle Center At X = 22.9 ; Y = 112.8 and Radius, 71.7 Factor of Safety ** 1.521 Failure Surface. Specified By 11 Coordinate Points C:\stedwin\p7686218..OUT Page 3 Point X-Surf Y-Surf No. (ft) (ft) 1 28.69 41.30 2 33.69 41.32 3 38.67 41.83 4 43.57 42.83 5 48.34 44.31 6 52.95 46.26 7 57.34 48.66 8 61.46. 51.48 9 65.29 54.69 10 68.79 58.27 11 71.81 62.06 Circle Center At X 31.0 ; Y = 91.6 and Radius, 50.4. Factor of Safety *** 1.525 ** Failure Surface Specified By 11 Coordinate Points Point X-Surf Y- Surf No. (ft) (ft) 1 28.69 41.30 2 33.46 42.82 3 38.17 44.48 4 42.84 46.28 5 47.45 48.22 6 52.00 50.29 7 56.49 52.49 8 60.91 54.02 9 65.27 57.28 10 69.54 59.87 11 72.99 62.10 Circle Center At X = -20.6 ; Y 204.1 and Radius, 170.1 Factor of Safety 1.535 *** Failure Surface Specified By 11 Coordinate Points Point X-Surf '1-Surf No. (ft) (.ft) 1 29.39 41.84 2 34.39 41.74 3 39.37 42.18 4 44.27 43.15 5.. 49.05 44.64 6 53.63 46.63 57.98 49.09 8 62.04 52.01 9. 65.77 55.35 10 69.11 59.06 11 71.27 62.04 Circle Center At X = 32.8 ; '1 = 88.4 and Radius, 46.7 Factor of Safety. *** .1.548 *** Failure Surface Specified By 11 Coordinate Points Point X-Surf '1-Surf No. (ft) (ft) 1 28.69 41.30 2 33.39 43.02 3 38.05 44.83 42.67 4.6.75 47.25 48.76 6 51.78 50.88 7 56.26 53.09 8 60.70 55.40 9 65.08 57.80 10 69.41 60.30 11. 72.35 62.08 Circle Center At X = -481 ; '1 = 259.0 and Radius, 230.8 Factor of Safety C:\stedwin\p-686218.OUT Page 4 ** 1.548 *' Failure Surface Specified By 12 Coordinate Points Point X-Surf Y- Surf No. (ft) (ft) 1 28.35 41.04 2 33.34 41.29 3 38.30 41.93 4 43.19 42.96 5 47.99 44.35 6 52.67 46.12 7 57.20 48.24 8 61.55 50.71 9 65.69 53.51 10 69.61 56.61 11 73.28 60.01 12 75.27 62.18 Circle Center AtX = 27.6 ;.Y = 105.3 and Radius, 64.3 Factor of Safety *** 1.567 *** Failure Surface Specified By 11 Coordinate Points Point X-Surf Y-Surf No. (ft) (ft) 1 28.00 40.77 2 32.59 42.75 3 37.16 44.77 4 41.72 46.84 5 46.25 48.95 6 50.76 .51.10 7 55.26 53.29 8 59.73 55.53 9 64.18 57.80 10 68.61 60.12 11 72.28 62.08 Circle Center At X -183.0 ; Y = 536.1 and Radius, 538.4 Factor of Safety *** 1.582 *** Failure. Surface Specified By 12 Coordinate Points Point X-Surf Y-Surf No. (ft) (ft) 1. 29.04 41.57 2 34.04 41.35 3 39.03 41.63 4 43.97 42.42 5 48.80 43.70 6 53.48 45.47 7 57.95 47.70 8 62.18 50.37 9 66.11 53.4.6 10 69.71 56.93 11 72.94: 60.75 12 73.89 62.13 Circle Center At X = 33.8 ; Y = 90.4 and Radius, 49..1 Factor of Safety 1.609 *** END OF GSTABL7 OUTPUT C:\stedwin\p-686218.OUT Page 1 *** GSTABL7 *** ** GSTABL7 by Garry H. Gregory, P.E. Original Version 1.0, January 1996; Current Version 2.0, September 2001 ** (All Rights Reserved-Unauthorized Use Prohibited) SLOPE STABILITY ANALYSIS SYSTEM Modified Bishop, Simplified Janbu, or GLE Method of Slices. (Includes Spencer & Morgenstern-Price Type Analysis) Including Pier/Pile, Reinforcement, Soil Nail, Tieback, Nonlinear Undrained Shear Strength, Curved Phi Envelope, Anisotropic Soil, Fiber-Reinforced Soil, Boundary Loads, Water Surfaces, Pseudo-Static Earthquake, and Applied Force Options. Analysis Run Date: 4/3/2018 Time of Run: 6:05PM Run By: MB/VS Input Data Filename C:p-686218. Output Filename: C:p-686218.OUT Unit System: English Plotted Output Filename: C:p-686218.PLT PROBLEM DESCRIPTION: LAGOON P-686218 BOUNDARY COORDINATES 9 Top Boundaries 9 Total Boundaries Boundary X-Left Y-Left X-Right Y-Right Soil Type No. (ft) (ft) (ft) (ft) Below End 1 0.00 25.00 5.00 25.00 2 2 5.00 25.00 11.00 30.00 2 3 11.00 30.00 27.00 40.00 2 4 27.00 40.00 40.00 50.00 1 5 40.00 50.00 57.00 60.00 1 6 57.00 60.00 70.00 62.00 1 7 70.00 62.00 100.00 63.00 1 8 100.00 63.00 136.00 63.00 1 9. 136.00 63.00 18.2.00 64.00 1 ISOTROPIC SOIL PARAMETERS 2 Type(s) of Soil Soil Total Saturated Cohesion Friction Pore Pressure Piez. Type Unit Wt. Unit Wt. Intercept Angle Pressure Constant Surface No. (pcf) (pcf) (psf) (deg) Param. (psf) No. 1 116.0 122.0 70.0 29.0 0.00 0.0 0 2 120.0 128.0 350.0 34.0 0.00 0.0 0 A Horizontal Earthquake Loading Coefficient OfO.160 Has Been. Assigned A Vertical Earthquake Loading Coefficient Of0.000 Has Been Assigned Cavitation Pressure = 0.0(psf) A Critical Failure Surface Searching Method, Using A Random Technique For Generating Circular Surfaces, Has Been Specified. 1250 Trial Surfaces Have Been Generated. 25 Surfaces Initiate From Each Of 50 Points Equally Spaced Along The Ground Surface Between X = 28.00(ft) and X = 45.00(ft) Each Surface Terminates Between X = 70.00(ft) and X = 110.00(ft) Unless Further Limitations Were Imposed, The Minimum Elevation At Which A Surface Extends Is Y = 0.00(ft) 5.00(ft) Line Segments Define Each Trial Failure Surface. Following Are Displayed The Ten Most Critical Of The Trial Failure Surfaces Evaluated. They Are Ordered - Most Critical First. * * Safety Factors Are Calculated By The Modified Bishop Method * Total Number of Trial Surfaces Evaluated = 1250 Statistical Data On All Valid FS Values: FS Max 3.436 FS Min = 1.087 FS Ave = 2.097 Standard Deviation = 0.545 Coefficient of Variation = 25.99 C:\stedwin\p-686218.OUT Page 2 Failure Surface Specified By 12 Coordinate Points Point X-Surf Y-Surf No. (ft) (ft) 1 28.69 41.30 2 33.66 41.88 3 38.57 42.81 4 43.41 44.07 5 48.15 45.67 6 52.77 47.59 7 57.24 49.83 B 61.54 52.37 9 65.66 55.21 10 69.57 58.33 11 73.25 61.71 12 73.64 62.12 Circle. Center At X = 22.9 ; y = 112.8 and Radius, 71.7 Factor of Safety *** 1.087 *** Individual data on the 14 slices Water Water Tie Tie Earthquake Force Force Force Force Force Surcharge Slice Width Weight Top Bot Norm Tan Hor Ver. Load No. (ft) (ibs) (ibs) (ibs) (ibs) (ibs) (ibs) (ibs) (ibs) 5.0 933.3 0.0 0.0 0.0 0.0 149.3 0.0 0.0 2 4.9 2660.8 0.0 0.0 0.0 0.0 425.7 0.0 0.0 3 1.4 1067.9 0.0 0.0 0.0 0.0 170.9 0.0 0.0 4 3.4 2920.3 0.0 _b.0 0.0 0.0 467.3 0.0 0.0 5 4.7 4688.9 0.0 0.0 0.0 0.0 750.2 0.0 0.0 6 4.6 5098.3 0.0 0.0 0.0 0.0 815.7 04 0.0 7 4.2 4962.5 0.0 0.0 0.0 0.0 794.0 0.0 0.0 8 0.2 281.2 0.0 0.0 0.0 0.0 45.0 0.0 0.0 9 4.3 4626.1 0.0 0.0 0.0 0.0 740.2 0.0 0.0 10 4.1 3448.9 0.0 0.0 0.0 0.0 551.8 0.0 0.0 11 3.9 2205.0 0.0 0.0 0.0 0.0 352.8 0.0 0.0 12 0.4 172.8 0.0 0.0 0.0 0.0 27.6 0.0 0.0 1.3 33 692.0 0.0 0.0 0.0 0.0 110.7 0.0 0.0 14 0.4 9.0 0.0 0.0 0.0 0.0 1.4 0.0 0.0 Failure Surface Specified By 11 Coordinate Points Point X-Surf Y-Surf No. (.ft) (ft) 1 29.39 41.81 2 34.14 43.38 .3 38.85 45.08 4 43.49 46.94 5 48.06 48.96 6 52.56 51.13 7 56.99 53.46 8 61.34 55.93 9 65.60 58.54- 10 69.77 61.30 11 70.78 62.03 Circle Center At X = -13.8 ; Y = 183.0 and Radius, 147.6 Factor of Safety 1.090 *** Failure Surface Specified By 11 coordinate Points Point X-Surf Y-Surf No. (ft) (ft) 1 28.00 40.77 2 32.68 42.52 3 37.33 44.•3 4 41.93 46.33 .5 46.49 48.38 6 . 51.06 50.54 7 55.47 52.78 8 59.88 55.13 9 64.25 57.57 C:\stedwin\p-686218.OUT Page 3 10 68.56 60.10 11 71.73 62.06 Circle Center At X = -50.8 ; I = 258.3 and Radius, 231.4 Factor of Safety *** 1.092 •** Failure Surface Specified By '11 Coordinate Points Point X-Surf I-Surf No. (ft) (ft) 1 28.69 41.30 2 33.46 42.82 3 38.17 44.48 4 42.84 46.28 5 47.45 48.22 6 52.00 50.29 7 56.49 52.49 8 60.91 54.82 9 65.27 57.28 10 69.54 59.87 11 72.99 62.10 Circle Center At X = -20.6 ; I = 204.1 and Radius, 170.1 Factor of Safety *** 1.094 *** Failure Surface Specified By 11 Coordinate Points Point X-Surf 1-Surf No. (ft) (ft) 1 28.69 41.30 2 33.69 41.32 3 38.67 41.83 4 43.57 42.83 5 48.34 44.31 6 52.95 46.26 7 57.34 48.66 8 61.46 51.48 9 65.29 54.69 10 68.79 58.27 11 71.81 62.06 Circle Center At X = 31.0 ; Y = 91.6 and Radius, 50.4 Factor of Safety *** 1.105 *** Failure Surface Specified By 11 Coordinate Points Point X-Surf 1-Surf No. (ft) (ft) 1 28.69 41.30 2 33.39 43.02 3 38.05 44.83 4 42.67 46.75 5 47.25 48.76 6 51.78 50.88 7 56.26 53.09 8 60.70 55.40 9 65.08 5'7.80 10 69.41 60.30 11 72.35 62.08 Circle Center At X = -48.1 ; I = 259.0 and Radius, 230.8 Factor of Safety 1.107 *** Failure Surface Specified By 12 Coordinate Points Point X-Surf 1-Surf No. (ft) (ft) 1 28.35 41.04 2 33.34 41.29 3 38.30 41.93 4 43.19 42.96 5 .47.99 44.35 6 52.67 46.12 7 57.20 48.24 C:\stedwin\p-686218.olJT Page 4 8 61.55 50.71 9 65.69 53.51 10 69.61 56.61 11 73.28 60.01 12 75.27 62.18 Circle Center At X = 27.6 ; Y = 105.3 and Radius, 64.3 Factor of Safety **+ 1.114 ** Failure Surface Specified By 11 Coordinate Points Point X-Surf Y-Surf No (ft) (ft) 1 29.39 41.84 2 34.39 4l74 3 39.37 42.18 4 44.27 43.15 5 49.05 44.64 6 53.63 46.63 7 57.98 49.09 8 62.04 52.01 9 65.7.7 55.35 10 69.11 59.06 11. 71.27 62.04 Circle center At X = 32.8 ; Y 88.4 and Radius, 46.7. Factor of Safety *** 1.122 *** Failure Surface Specified By 11 Coordthate Points Point X-Surf Y-Surf No. (ft) (ft) 1 28.00 40.77 2 32.59 42.75 3 37.16 44.77 4 41.72 46.84 5. 46.25. 48.95 6 50.76 51.10 7 55.26 . 53.29 8 59.73 55.53 9 64.18 57.80 10 68.61 60.12 11 72.28 62.08 Circle Center At X = -183.0 ; Y = 536.1 and Radius, 538.4 Factor of Safety *** 1.133 ** Failure Surface Specified By 11 Coordinate Points Point X-Surf Y-Surf No. (ft) (ft) 1 30.08 42.37 2 34.82 43.97 3 39.52 45.66 4. 44.19 47.46 5 48.82 49.35 6 53.40 51.34 7 57•95 5343 8 62.44 55.62 9 66.89 57.90 10 71.29 60.28 11 7.4.59 62.15 Circle Center At X = -42.2 ; Y = 265.1 and Radius, 234.2 Factor of Safety 1.149 *** END OF GSTABL7 OUTPUT APPENDIX 'D Grading Guidelines Grading should be performed to at least the minimum requirements of the local governing agencies, the California Building Code, 2016, the geotechnical report and the guidelines presented below. All of the guidelines may not apply to a specific site and additional recommendations may be necessary during the grading phase. Site Clearing Trees, dense vegetation, and other deleterious materials should be removed from the site. Nonorgathc debris or concrete may be placed in deeper fill areas under direction of the Soils engineer. Subdrainage During grading, the Geologist and Soils Engineer should evaluate the necessity of placing additional drains. All subdrainage systems should be observed by the Geologist and Soils Engineer during construction and prior to covering with compacted fill. Consideration should be given to having subdrains located by the project surveyors. Outlets should be located and protected. Treatment of Existing Ground All heavy vegetation, rubbish and other deleterious materials should be disposed of off site. All surficial deposits including alluvium and colluvium should be removed unless otherwise indicated in the text of this repOrt. Groundwater existing in the alluvial areas may make excavation difficult. Deeper removals than indicated in the text of the report may be necessary due to saturation during winter months. Subsequent to removals, the natural ground should be processed to a• depth of six inches, moistened to near optimum moisture conditions and compacted to fill standards. Fill Placement Most site soil and bedrock may be reused for compacted fill; however, some special processing or handling may be required (see report). Highly organic or contaminated soil should not be used for compacted fill. Material used in the compacting process should be evenly spread, moisture conditioned, processed, and compacted in thin lifts not to exceed six inches in thickness to obtain a uniformly dense layer. The fill should be placed and compacted on a horizontal plane, unless otherwise found acceptable by the Soils Engineer. If the moisture content or relative density varies from that acceptable to the Soils engineer, the Contractor should rework the fill until it is in accordance with the following: Moisture content of the fill should be at or above optimum moisture. Moisture should be evenly distributed without wet and dry pockets. Pre-watering of cut or removal areas should be considered in addition to watering during fill placement, particularly in clay or dry surficial soils. Each six inch layer should be compacted to at least 90 percent of the maximum density in compliance with the testing method specified by the controlling governmental agency. In this case, the testing method is ASTM Test Designation D-1557-91. Side-hill fills should have a minimum equipment-width key at their toe excavated through all surficial soil and into competent material (see report) and tilted back into the hill. As the fill is elevated, it should be benched through surficial deposits and into competent bedrock or other material deemed suitable by the Soils Engineer. Rock fragments less than six inches in diameter may be utilized in the fill, provided: They are not placed in concentrated pockets; There is a sufficient percentage. of fine-grained material to surround the rocks; The distribution of the rocks is supervised by the Soils Engineer. Rocks greater than six inches in diameter should be taken off site, or placed in accordance with the recommendations of the Soils Engineer in areas designated as suitable for rock disposal. In clay soil large chunks or blocks are common; if in excess of six (6) inches minimum dimension then they are considered as oversized. Sheepsfoot compactors or other suitable methods should be used to break the up blocks. The Contractor should be required to obtain a minimum relative compaction of 90 percent out to the finished slope face of fill slopes. This may be achieved by either overbuilding the slope and cutting back to the compacted core, or by direct compaction of the slope face with suitable equipment. If fill slopes are built "at grade" using direct compaction methods then the slope construction should be performed so that a constant gradient is maintained throughout construction. Soil should not be "spilled" over the slope face nor should slopes be "pushed out" to obtain grades. Compaction equipment should compact each lift along the immediate top of slope. Slopes should be back rolled approximately every 4 feet vertically as the slope is built. Density tests should be taken periodically during grading on the flat surface of the fill three to five feet horizontally from the face of the slope. In addition, if a method other than over building and cutting back to the compacted core is to be employed, slope compaction testing during construction should include testing the outer six inches to three feet in the slope face to determine if the required compaction is being achieved. Finish grade testing of the slope should be performed after construction is complete. Each day the Contractor should receive a copy of the Soils Engineer's "Daily Field Engineering Report' which would indicate the results of field density tests that day. Fill over cut slopes should be constructed in the following manner: All surficial soils and weathered rock materials should be removed at the cut-fill interface. A. key at least 1 equipment width wide (see report) and tipped at least 1 foot into slope should be excavated into competent materials and observed by the Soils Engineer or his representative. The cut portion of the slope should be constructed prior to fill placement to evaluate if stabilization is necessary, the contractor should be responsible for any additional earthwork created by placing fill prior to cut excavation. Transition lots (cut and fill) and lots above stabilization fills should be cappe4 with a four foot thick compacted fill blanket (or as indicated in the report). Cut pads should be observed by the Geologist to evaluate the need for overexcavation and replacement with fill. This may be necessary to reduce water infiltration into highly fractured bedrock or other permeable zones, and/or due to differing expansive. potential of materials beneath a structure. The overexcavation should be at least three feet. Deeper overexcavation may be recommended in some cases. Exploratory backhoe or dozer trenches still remaining after site removal should be excavated and filled with compacted fill if they can be located. Grading Observation and Testing Observation of the fill placement should be provided by the Soils Engineer during the progress of grading. In general, density tests would be made at intervals not exceeding two feet of fill height or every 1,000 cubic yards of fill placed. This criteria will vary depending on soil conditions and the size of the fill. In any event, an adequate number of field density tests should be made to evaluate if the required compaction and moisture content is generally being obtained. Density tests may be made on the surface material to receive fill, as required by the Soils Engineer. Cleanouts, processed ground to receive fill, key excavations, subdrains and rock disposal should be observed by the Soils Engineer prior to placing any fill. It will be the Contractor's responsibility to notify the Soils Engineer when such areas are ready for observation. A. Geologist should observe subdrain construction. A Geologist should observe benching prior to and during placement of fill. Utility Trench Bacicfihl Utility trench backfill should be placed to the following standards: Ninety percent of the laboratory standard if native material is used as backfill. As an alternative, clean sand may be utilized and flooded into place. No specific relative compaction would be required; however, observation, probing, and if deemed necessary, testing may be required. Exterior trenches, paralleling a footing and extending below a 1:1 plane projected from the outside bottom edge of the footing, should be compacted to 90 percent of the laboratory standard. Sand backfill, unless it is similar to the inplace fill, should not be allowed in these trench-backfill areas. Density testing along with probing should be accomplished to verify the desired results.