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HomeMy WebLinkAbout2015-3729 - Ordinance - 12/10/2015ORDINANCE NO. 2015-3729 AN ORDINANCE OF THE CITY OF COLLEGE STATION, TEXAS, AMENDING THE COLLEGE STATION COMPREHENSIVE PLAN BY AMENDING CHAPTER 6 "TRANSPORTATION" AND CERTAIN MAPS WITHIN THE "BICYCLE, PEDESTRIAN, AND GREENWAYS MASTER PLAN;" UPDATING AND STREAMLINING PRESENTATION OF INFORMATION RELATING TO TRANSPORTATION; PROVIDING A SEVERABILITY CLAUSE; PROVIDING AN EFFECTIVE DATE; AND CONTAINING OTHER PROVISIONS RELATED THERETO. BE IT ORDAINED BY THE CITY COUNCIL OF THE CITY OF COLLEGE STATION, TEXAS: PART 1: PART2: PART3: PART 4: PART 5: That the "Comprehensive Plan of the City of College Station" is hereby amended by adding new subsections C.1.b, C.4.i and C.5.b to Exhibit "A" thereto as set out in Exhibit "A" attached hereto and made a part hereof for all purposes. That the "Comprehensive Plan of the City of College Station" is hereby amended by deleting Chapter 6/Transportation thereof and substituting therefor a new Chapter 6/Transportation as set out in Exhibit "B" attached hereto and made a part hereof for all purposes. That the "Comprehensive Plan of the City of College Station" is hereby amended by amending Map 5.4 "Proposed Bicycle Facilities and Map," and Map 5.5 "Proposed Pedestrian Facilities" of the Bicycle, Pedestrian, and Greenways Master Plan dated January 2010 to maintain the alignment of said facilities shown on said maps with the changes made to the alignment of streets as shown on the Thoroughfare Plan Map 6.1 in Chapter 6/Transportation as amended in this Ordinance. That if any provisions of any section of this ordinance shall be held to be void or unconstitutional, such holding shall in no way effect the validity of the remaining provisions or sections of this ordinance, which shall remain in full force and effect. That any person, firm, or corporation violating any of the provisions of this chapter shall be deemed guilty of a misdemeanor, and upon conviction thereof shall be punishable by a fine of not less than Twenty-five Dollars ($25.00) nor more than Two Thousand Dollars ($2,000.00). Each day such violation shall continue or be permitted to continue, shall be deemed a separate offense. Said Ordinance, being a penal ordinance, becomes effective ten (10) days after its date of passage by the City Council, as provided by Section 35 of the Charter of the City of College Station. ORDINANCE NO. 2015-3729 Page 2 of45 PASSED, ADOPTED and APPROVED this 10th day of December, 2015. ATTEST: City Attorney ORDINANCE NO. 2015-3729 Page 3 of 45 EXHIBIT "A" That ordinance no. 3186 adopting the "Comprehensive Plan of the City of College Station" as amended, is hereby amended by adding new subsections C.1.b, C.4.i and C.5.b to Exhibit "A" of said plan for Exhibit "A" to read in its entirety as follows: "EXHIBIT 'A' A. Comprehensive Plan The College Station Comprehensive Plan (Ordinance 3186) is hereby adopted and consists of the following: 1. Existing Conditions; 2. Introduction; 3. Community Character; 4. Neighborhood Integrity; 5. Economic Development; 6. Parks, Greenways & the Arts; 7. Transportation; 8. Municipal Services & Community Facilities; 9. Growth Management and Capacity; and 10. Implementation and Administration. B. Master Plans The following Master Plans are hereby adopted and made a part of the College Station Comprehensive Plan: 1. The Northgate Redevelopment Plan dated November 1996; 2. The Revised Wolf Pen Creek Master Plan dated 1998; 3. Northgate Redevelopment Implementation Plan dated July 2003; 4. East College Station Transportation Study dated May 2005; 5. Parks, Recreation and Open Space Master Plan dated May 2005; 6. Park Land Dedication Neighborhood Park Zones Map dated January 2009; 7. Park Land Dedication Community Park Zones map dated April 2009; 8. Bicycle, Pedestrian, and Greenways Master Plan dated January 2010; 9. Central College Station Neighborhood Plan dated June 2010; 10. Water System Master Plan dated August 2010; 11. Wastewater Master Plan dated June 2011; 12. Eastgate Neighborhood Plan dated June 2011; 13. Recreation, Park and Open Space Master Plan dated Jul y 2011; 14. Southside Area Neighborhood Plan dated August 2012; 15. Medical District Master Plan dated October 2012; 16. Wellborn Community Plan dated April 2013; 17. Economic Development Master Plan dated September 2013; and ORDINANCE NO. 2015-3729 Page 4 of 45 18. South Knoll Area Neighborhood Plan dated September 2013. C. Miscellaneous Amendments The following miscellaneous amendments to the College Station Comprehensive Plan are as follows: 1. Text Amendments: a. Chapter 2 "Community Character," "Growth Areas" by amending the text regarding Growth Area IV and Growth Area V -Ordinance 3376, dated October 2011. b. Chapter 6 "Transportation" by amending the text regarding Complete Streets, Context Sensitive Solutions, Minimum Length and Additional Right-of-Way for Turn Lanes at Intersections, and Right-of-Way for Utilities with this ordinance, dated December 10, 2015. 2. Future Land Use and Character Map Amendment: a. 301 Southwest Parkway-Ordinance 3255, dated July 2010. b. Richards Subdivision -Ordinance 33 76, dated October 2011. c. 1600 University Drive East-Ordinance 3535, dated November 14, 2013. d. 2560 Earl Rudder Freeway S. -Ordinance 3541, dated December 12, 2013. e. 13913 FM 2154. -Ordinance 3546, dated January 9, 2014. f. 2021 Harvey Mitchell Parkway-Ordinance 3549, dated January 23, 2014. g. 1201 Norton Lane -Ordinance 3555, dated February 27, 2014. h. 3715 Rock Prairie Road West-Ordinance 3596, dated August 25, 2014. i. 4201 Rock Prairie Road-Ordinance 2015-3670, dated July 9, 2015. 3. Concept Map Amendment: a. Growth Area IV -Ordinance 3376, dated October 2011. b. Growth Area V -Ordinance 3376, dated October 2011. 4. Thoroughfare Map Amendment: a. Raintree Drive -Ordinance 3375, dated October 2011. b. Birkdale Drive -Ordinance 3375, dated October 2011. c. Corsair Circle -Ordinance 3375, dated October 2011. d. Deacon Drive -Ordinance 3375, dated October 2011. e. Dartmouth Drive -Ordinance 3375, dated October 2011. f. Farm to Market 60 -Ordinance 3375, dated October 2011. g. Southwest Parkway-Ordinance 3375, dated October 2011. h. Cain Road extension -O rdinance 3639, dated February 26, 2015. i. Updates to Maps within new Chapter 6 of the College Station Comprehensive Plan - with this ordinance, dated December 10, 2015. 5. Bicycle, Pedestrian and Greenways Master Plan Amendment: D. General a. Cain Road extension-Ordinance 3639, dated February 26, 2015. b. Updates to Maps 5.4 and 5.5 -with this ordinance, dated December 10, 2015. ORDINANCE NO. 2015-3729 Page 5 of 45 I. Conflict. All parts of the College Station Comprehensive Plan and any amendments thereto shall be harmonized where possible to give effect to all. Only in the event of an irreconcilable conflict shall the later adopted ordinance prevail and then only to the extent necessary to avoid such conflict. Ordinances adopted at the same city council meeting without reference to another such ordinance shall be harmonized, if possible, so that effect may be given to each. 2. Purpose. The Comprehensive Plan is to be used as a guide for growth and development for the entire City and its extra-territorial jurisdiction ("ETJ"). The College Station Comprehensive Plan depicts generalized locations of proposed future land-uses, including thoroughfares, bikeways, pedestrian ways, parks, greenways, and waterlines that are subject to modification by the City to fit local conditions and budget constraints. 3. General nature of Future Land Use and Character. The College Station Comprehensive Plan, in particular the Future Land Use and Character Map and any adopted amendments thereto, shall not be nor considered a zoning map, shall not constitute zoning regulations or establish zoning boundaries and shall not be site or parcel specific but shall be used to illustrate generalized locations. 4. General nature of College Station Comprehensive Plan. The College Station Comprehensive Plan, including the Thoroughfare Plan, Bicycle, Pedestrian, and Greenways Master Plan, Central College Station Neighborhood Plan, Water System Master Plan and any additions, amendments, master plans and subcategories thereto depict same in generalized terms including future locations; and are subject to modifications by the City to fit local conditions, budget constraints, cost participation, and right-of-way availability that warrant further refinement as development occurs. Linear routes such as bikeways, greenways, thoroughfares, pedestrian ways, waterlines and sewer lines that are a part of the College Station Comprehensive Plan may be relocated by the City 1,000 feet from the locations shown in the Plan without being considered an amendment thereto. 5. Reference. The term College Station Comprehensive Plan includes all of the above in its entirety as if presented in full herein, and as same may from time to time be amended." ORDINANCE NO. 2015-3729 Page 6 of 45 EXHIBIT "B" That the "Comprehensive Plan of the City of College Station" is hereby amended by deleting Chapter 6/Transportation thereof and substituting therefor a new Chapter 6/Transportation to provide in its entirety as follows: Ordinance No. 2015-3729 EXHIBIT B Page 7 of 45 By living in a growing university community, College Station residents have mobility options beyond the private automobile, including designated bike routes, an extensive sidewalk network, and local transit services. As Amended 12-10-15 Residents have voiced their support for a transportation network that better manages congestion; offers more travel options and choices; and is sensitive to the neighborhoods, natural areas, and districts. The challenges facing the current transportation system demand strategic thought about how College Station plans land uses, designs projects, and makes the system more bike friendly and walkable. It is also necessary that significant expenditures be made to add capacity to our existing roadways and to build new streets. The City must also keep planning for to ensure adequate right-of-ways exist to accommodate the needs of future generations, while not compromising future transportation options. Developing a successful transportation plan requires a thorough understanding of current conditions, opportunities, challenges, and preferred outcomes. PURPOSE The purpose of this chapter is to ensure orderly and integrated development of the community's transportation network, considering not only facilities for automobiles, but also transit, bicycles, and pedestrians. This chapter includes the Thoroughfare Plan, identifying the network's roadway needs for the next 20 years. It also includes an overview of the planning considerations associated with the City's transportation needs and a discussion of context sensitive solutions. It also serves as the foundation for the Bicycle, Pedestrian, and Greenways Master Plan. Finally, there is the identification of strategies and action recommendations that will facilitate the development of the transportation system. EXISTING MOBILITY Street Network The thoroughfare network in College Station and its Extraterritorial Jurisdiction consists of more than 200 miles of existing streets. The freeways and a Transportation I As Amended 12-10-15 majority of the arterial streets are part of the Texas Department of Transportation system, with the remainder planned, built, and maintained by the City and Brazos County. Many of the freeway and arterial streets have seen dramatic increases in traffic volumes over the past decade, necessitating substantial capacity improvement projects, such as the widening of Texas Avenue, interchange improvement on State Highway 6, and improvements on Wellborn Road (FM 2154) and Harvey Mitchell Parkway (FM 2818). Current traffic counts on various roadways across the community are displayed in Map 6.1, Existing Traffic Volumes. Increases in traffic volumes have resulted in peak hour congestion along certain corridors and at specific intersections. These hotspots are dispersed throughout the City, but tend to be found most often where two high-volume roadways intersect. In addition to increases in traffic volume, intersection design, traffic signal operations, driveway locations, and adjacent land uses each contribute to the decreased service levels in these hotspots. The College Station: Existing Conditions report, prepared to accompany this Plan, provides detailed information about the current thoroughfare network. The level of service on area roadways in 2007 is displayed in Map 6.2, 2007 Level of Service. Transit A variety of organizations provide transit service in College Station, with the primary provider being Texas A&M University. Other providers include The District and the Brazos Valley Area Agency on Aging. Additionally, the College Station Independent School District operates a large fleet of buses used to transport students to and from its schools. Texas A&M University has operated a transit system for students, employees, and on-campus visitors since 1982. The system currently consists of 95 buses operating 13 off-campus routes in the cities of Bryan and College Station, every day of the week. In addition to these fixed off-campus routes, the system also includes seven on-campus routes, a door-to-door shuttle service for disabled students and employees, an airport shuttle between campus and Easterwood Airport, and charter services. During home football games, special game day transportation is provided, shuttling riders between the campus and park-and-ride lots located at Post Oak Mall. Based on the latest available data, the daily ridership on the fixed off-campus routes averaged more than 18,000 passengers and on-campus routes averaged nearly 15,000 passengers (2004). The District, first established as the Brazos Transit System, has operated transit routes for the general public since 1982. Services extend across a 16-county area in southeastern Texas. The system currently operates eight fixed-routes in the cities of Bryan and College Station, Monday Ordinance No. 2015-3729 As Amended 12-10-15 I Transportation through Friday. In addition to these fixed-routes, the system also includes limited door-to-door services for elderly and disabled residents and demand response (by schedule) door-to-door services, with a preference to persons with medical appointments. Based on the latest available data, the annual ridership for the system in the cities of Bryan and College Station was more than 270,000 passengers (2001 ). Map 6.3, Existing Transit Routes, displays the existing bus transit routes in College Station and Bryan. The Brazos Valley Area Agency on Aging operates a demand response (by schedule) door-to-door service for elderly residents of College Station with a preference to persons with medical appointments. This service is coordinated through the Brazos Valley Council of Governments. The College Station Independent School District operates a fleet of 48 buses, including eight buses designed and used for special needs. Currently, the system consists of 42 routes serving 12 schools and more than 2,500 of the 9,000 students enrolled in the district. Bicycle and Pedestrian Facilities College Station currently accommodates bicyclists by on-street bike lanes, off-street multi-use paths, and signed bicycle routes. Pedestrians Sryan/Collog• Station Transit Ravi•• Legend >-•-·•-Allo�Trt�s.IRwles Page 10 of 45 Transportation I As Amended 12-10-15 are accommodated by a network of sidewalks and multi-use paths. Over the past couple of decades, the City has adopted a series of master plans addressing the bicycle and pedestrian needs of the community. Each of these plans has initiated actions and funding approvals by residents, resulting in 32 miles of on-road bike lanes, three miles of off-road multi-use paths, 50 miles of signed bicycle routes, and l 06 miles of sidewalks dispersed throughout the City. Texas A&M University has a similar network, facilitating bicycle and pedestrian movements on campus. Aviation Easterwood Airport connects the City of College Station to other metropolitan areas of Texas and the Nation. The airport has been owned and operated by Texas A& M University since 1938 and is served by two commercial airlines, as well as offering general aviation services. The airport encompasses nearly 700 acres, including three runways - one primary and two crosswind runways. The airport includes a passenger terminal constructed in 1990 and recently remodeled, as well as a general aviation terminal remodeled in 1994. Recent data (2005) indicates the airport had total aircraft operations of more than 60,000, with more than 603 of the operations involving general aviation aircraft. In 2008, the airport served more than 150,000 passengers through commercial operations, slightly fewer than the numbers served in the preceding year. Pending Projects The City of College Station and other regional transportation providers, through partnership with the Bryan-College Station Metropolitan Planning Organization, have identified transportation projects needed to meet increasing demands. These projects are identified in a number of plans and studies, but most important are those projects identified in the City's Capital Improvements Program, the City's most recent bond approval, the State's Transportation Improvement Program, and the Metropolitan Planning Organization's Transportation Improvement Program. These documents identify projects that have funding either authorized or appropriated for land acquisition, design, and construction, and are therefore imminent. Projects on these lists include the following: • State Highway 6 ramp and interchange improvements; • Barron Road -State Highway 6 interchange construction; • Barron Road widening; • William D. Fitch Parkway widening; • FM 2154 and FM 2818 grade separation; • Bee Creek Trail design and construction; Ordinance No. 2015-3729 As Amended 12-10-15 I Transportation • Spring Creek Trail design and construction; and, • Texas A&M University bus system improvements. For a complete list and project details, consult the documents previously referenced. PLANNING CONSIDERATIONS FIGURE 6.1 Activities Analyzed by Travel Demand Model Future Conditions With the population projected to increase by approximately 40,000 persons by 2030, traffic, too, is expected to increase substantially. With increased traffic comes the potential for increased congestion and degradation of levels of service. However, this growth will also increase the demand for pedestrian, bicycle, and transit facilities. A travel demand model was prepared for this Plan, in the manner depicted in Figure 6.1, Activities Analyzed by Travel Demand Model, using projected population and employment growth based on the Future Land Use & Character map. The model was used to aid in the determination of Urban Activity � L Roadway Route Choice � the transportation network needs, to refine the Future Land Use & Character map, and for identification and prioritization of the recommended capital expenditures. Without significant investments in new and expanded roadways, pedestrian and bicycle facilities, and transit, the estimated travel demand will result in increased congestion and a degradation of level of service in numerous locations. To be successful, transportation investments must be accompanied by significant increases in transit ridership and the reduction of vehicle trip and travel distance through better land use planning, increased use of bicycles, and improved walkability. Map 6.4, 2030 Lanes with Programmed Projects, displays the number of lanes required to accommodate the projected traffic volumes in 2030. Map 6.5, 2030 Traffic Volumes with Programmed Pr ojects, displays the projected traffic volumes on College Station roadways in 2030. Regional Transportation Network The City of College Station is only one of many entities involved in the planning, construction, and operation of transportation facilities. The Bryan-College Station Metropolitan Planning Agency, the Brazos Valley Council of Governments, and the Texas Department of Transportation each have their own role in transportation planning, funding, --Trip Frequency l Destination choice l Mode Choice ! aaaa @: ...... " i Transit Route Choice Page 12 of 45 Transportation I As Amended 12-10-1 s construction, and maintenance. The Metropolitan Planning Organization serves as the regional partnership that coordinates regional transportation planning and manages federal transportation funding that comes to the region. The Organization maintains the region's Metropolitan Transportation Plan and the Transportation Improvement Program. The Brazos Valley Council of Governments is a regional partnership focused on a variety of topics of importance to its members. The Council is involved in planning for and operating transit services for the elderly through the Area Agency on Aging. The Council also assists the City in its involvement with the Texas High Speed Rail Initiative and the establishment of a regional mobility authority. The Texas Department of Transportation is responsible for planning, constructing, and operating most of the City's primary mobility corridors, including State Highway 6, Harvey Road (State Highway 30), William D. Fitch (State Highway 40), Harvey Mitchell Parkway (FM 2818), Wellborn Road (FM 2154), and Texas Avenue. The Department also partners with the City to enhance landscaping within State highway rights-of-way, bicycle facilities funding, and railroad crossing safety improvements. It is critical that transportation planning in the City be coordinated with each of these partners so that the City's transportation system supports the mobility needs of the region. Transit Transit will need to play an increasing role in the City's transportation system in order to provide travel choices and minimize expenses in expanding roadway capacity. While providing valuable services and congestion relief today, the fragmented and limited system of current transit services will not be sufficient to meet future needs. The City is a partner in the Texas High Speed Rail Initiative which, if constructed, would provide high-speed commuter rail services to College Station, connecting it to the major metropolitan areas of eastern Texas. Bicycle and Pedestrian Facilities Expanded bicycle and pedestrian facilities, as part of an integrated multi-modal transportation network, needs to offer alternatives to vehicular travel and aid in reducing the vehicle miles traveled, and thus the costs associated with extensive roadway expansion. Aviation Continued modernization of Easterwood Airport and protection from incompatible land uses are essential to the long-term viability of airport operations. The presence of commercial airline service adds a critical and valuable element to both the City's transportation network and to its competitive advantage over other areas in the region. Ordinance No. 2015-3729 As Amended 12-10-15 I Transportation Connectivity Poor transportation connectivity can degrade the overall efficiency of the transportation network as the majority of trips are funneled to a few corridors. Connectivity in College Station is limited, especially where constrained by natural features, such as floodplains. Neighborhood opposition and development oriented around cul-de-sacs has limited connectivity in the City. Future transportation system effectiveness necessitates improved connectivity to facilitate multiple routes to move traffic to and from destinations. Otherwise, traffic congestion will increase and will increasingly push additional traffic through neighborhoods. Increased connectivity must be balanced with resource protection and neighborhood concerns. Connectivity with and to each of the travel modes is crucial to future accessibility and mobility. Context sensitive design and traffic calming measures are essential components of any effort at increased connectivity. Extraterritorial Jurisdiction This Plan proposes a land use pattern and growth management efforts that, if successful, will minimize the amount and intensity of development occurring in the Extraterritorial Jurisdiction. Still, the Extraterritorial Jurisdiction will continue to see some level of development. It will also continue to expand in size through annexation and should therefore be connected to the rest of the planning jurisdiction. It is essential, though not currently necessary for capacity, that the Thoroughfare Plan in the Extraterritorial Jurisdiction ensure the reservation of adequate rights-of-way in a pattern that is dense enough to provide connectivity through the area beyond this planning horizon. Relationship to Land Use Pattern A very close relationship exists between the transportation network and the land use pattern. For example, high-volume six-lane roads, designed exclusively for the private automobile, tend to attract uses such as big-box retail and large apartment complexes, while repelling other land uses such as single-family homes. In a similar manner, land uses arranged in a mixed-use, dense pattern can reduce the frequency and length of vehicular trips, and if designed properly, can promote walking, biking, and transit use, therefore reducing the demand placed on the street network. The Concept Map and Future Land Use & Character map define an approach to land use planning and design that, when combined with the proposed context sensitive solutions approach, will strengthen the transportation-land use relationship in a positive manner. Bus Rapid Transit (BRT) is a broad tenn given to a variety of transpo1tation systems that, through improvements to infrastructure, vehicles and scheduling, attempt to use buses to provide a service that is of a higher quality than an ordinary bus line. The goal of such systems is to approach the service quality of rail transit, in terms of timeliness and amenities, while still enjoying the cost savings of bus transit relative to more capital intensive rail systems. Context Sensitive Solutions (CSS) is a different approach to the design and planning of transportation projects. lt balances the competing needs of stakeholders early on in the decision mal<lng process. its benefit comes from the flexibility in the application of projects based on different standards and different transportation modes. Transportation I As Amended 12-10-15 Build-out Conditions Though beyond the scope, the framework of this Plan must, consider the transportation needs of the community as it approaches build-out, that is, as it approaches the complete development of all developable land in the City. This is necessary to ensure that actions taken within this planning time-frame do not preclude future options. Even better, it is to ensure that actions taken within this planning time-frame actually offer more opportunities for future decision-makers. An example of this approach is ensuring that rights-of-way are reserved in the Extraterritorial Jurisdiction for a future street system, even though this capacity is not expected to be necessary within this planning timeframe. This Plan projects a 2030 population of approximately 134,000. The Future Land Use & Character map contained in this Plan identifies land uses capable of accommodating an ultimate population of approximately 196,000 within the current City limits. Planning for land uses capable of accommodating a larger population than is projected for the City provides a margin of error and allows for market flexibility. The transportation network needed to serve the build-out population could differ considerably from that proposed to serve the projected 2030 population. More efficient and higher capacity streets, increased access management along heavily traveled corridors, increased reliance on transit, bicycling, and walking, and the emergence of dense mixed-use development are just a few of the possible needs to serve the build-out population. This Plan must respond to this possible future by providing a high level of connectivity with and to each travel mode; ensuring that rights-of-way are appropriate to accommodate future roadway expansion; access management is employed where appropriate; street designs promote multi-modal solutions and allow expansion into services such as bus rapid transit; and land use designations enable dense mixed-use development where and when appropriate and necessary. CONTEXT SENSITIVE SOLUTIONS This Plan proposes the use of context sensitive solutions to meet the City's transportation needs and support its land use and character objectives. Context sensitive solutions, as promoted by The Federal Highway Administration and the Institute of Transportation Engineers, is a way of planning and building a transportation system that balances the many needs of diverse stakeholders and offers flexibility in the application of design controls, guidelines, and criteria, resulting in facilities that are safe and effective for all users regardless of the mode of travel they choose. The basic principles of context sensitive solutions include (Context Sensitive Solutions in Designing Major Urban Ordinance No. 2015-3729 As Amended 12-10-15 I Transportation Thoroughfares for Walkable Communities, ITE: 2006): • Balance safety, mobility, community and environmental goals in all projects; • Involve the public and stakeholders early and continuously throughout the planning and project development process; • Use an interdisciplinary team tailored to project needs; • Address all modes of travel; • Apply flexibility inherent in design standards; and, • Incorporate aesthetics as an integral part of good design. The use of context sensitive solutions in transportation planning can help ensure projects respond to the community's transportation needs, values, and vision for the future, helping specific projects move from design to construction faster and with less objection. This Plan includes the long-range planning of the transportation system, in which context sensitive solution facilitates the planning of a transportation network integrated into the long-range land use and character strategies of the City. This approach allows the City to define the mobility needs of each of the system users. The transportation network should ensure reservation of rights-of-way needed for the ultimate thoroughfare width based on long-term need. The spacing of thoroughfares should be standardized and support the strategies of the Plan. For example, arterials spaced as far as one-mile apart may carry the anticipated traffic but will likely require six lanes, which may be inappropriate for some contexts. Closer spacing of arterials could carry the same volume of traffic but reduce the number of lanes necessary. Likewise, collectors spaced close together (one-eighth mile) result in lower block lengths and promote greater pedestrian and bicycling activities. Local streets should connect as frequently as practical to the collector network to keep block lengths short and to promote connectivity throughout the system. In general, context sensitive solutions are focused on streets that play the most significant roles in the local transportation network and that offer the greatest multi-modal opportunities -arterials and collectors. Primary mobility routes or freeways, such as State Highway 6, are generally intended to move very high volumes of high-speed traffic through College Station, providing connections to the larger region. These streets should be the focus of their own unique planning and design process and are discussed elsewhere in this chapter. Similarly, local or residential streets are generally not the focus of context sensitive solutions, while they should be designed to accommodate bicycles and pedestrians and should be interconnected to one another and into the larger transportation network. Page 15 of 45 Ordinance No. 2015-37 9 Page 16 of 45 Transportation I As Amended 12-10-15 THOROUGHFARE PLAN The Thoroughfare Plan is based on the projected transportation demand resulting from the anticipated growth in population and employment and is guided by the proposed Future Land Use & Character map. In the development of the Thoroughfare Plan, a travel demand model was used to project the increase in vehicle trips. This information was used to identify the purpose of the various transportation corridors -that is what they need to function as, such as an arterial or collector. This information also aided in identifying the location of new roads needed either for capacity enhancements or to provide connectivity, as well as the number of lanes needed for each of the streets in the network. Three transportation network scenarios were developed based on results from the travel demand model. Each of these scenarios were tested against the community's goals and preferences identified in the development of this Plan. This testing resulted in the selection of a preferred scenario adopted as part of this Plan. Each of the scenarios considered is briefly discussed in the following. The selected scenario is further described through the accompanying maps and graphics. Current-Network Option This scenario would focus future efforts on maintaining the streets and lanes currently in place, with the additional construction of new streets to serve private development. This scenario would result in increased congestion and degradation of levels of service in some of the busiest areas. Although some locations may experience unacceptable levels of congestion and delay, much of the network will likely continue to function at acceptable levels of service. It is also possible that the scenario would promote a greater reliance on transit or alternative modes of travel, though without the construction of additional facilities, the success of even these options is questionable. Though offering some advantages, such as more efficient use of some of the road corridors, affordability, and increased use of alternative modes of travel, this scenario was rejected due to the increase in unacceptable levels of congestion, which conflicts with the community's desire to manage and reduce congestion. Programmed-Project Option This scenario focuses future efforts on expanding the capacity of existing streets, adding new streets and increasing multi-modal facilities and options as currently programmed -that is projects that have funding authorized or appropriated. This scenario would result in the construction of more than 130 lane miles in addition to the construction of local streets necessary to serve private development, several miles of off-street multi-use paths, and continued maintenance of the existing Ordinance No. 2015-3729 As Amended 12-10-15 I Transportation transit system. It is anticipated this scenario would require more than $200 million (in 2009 dollars) in public funds, as well as expenditures by development interests on streets serving private development. This scenario accommodates the projected increase in vehicle miles; however it also results in a slight increase in congestion and degradation of levels of service in specific areas along the network. This scenario is dependent on an increase in the use of alternative modes of travel, which could be encouraged through multi-modal design with the new construction. A modified version of this scenario has been selected as the preferred scenario due to its fiscal practicality, its ability to support expansion of multi-modal opportunities, and its response to the community desire to manage and reduce congestion. This option necessitates land use planning that promotes alternative modes of transportation and reduces the frequency and length of vehicular trips. Additionally, the selected option requires an increased investment in transit and enhancement of the Thoroughfare Plan in the Extraterritorial Jurisdiction to reserve rights-of-way for future needs and facilitates connectivity. Congestion-Reduction Option This scenario focuses future efforts on substantial expansion of roadway capacity and the construction of new streets. This scenario would result in the construction of more than 440 lane miles in addition to the construction of local streets necessary to serve private development, several miles of off-street multi-use paths, and continued maintenance of the existing transit system. It is anticipated this scenario would require more than $650 million (in 2009 dollars) in public funds, as well as expenditures by development interests on streets serving private development. This scenario accommodates the projected increase in vehicle miles, with a decrease in congestion and maintenance or improvement in levels of service throughout the network. This scenario is dependent on an increase in the use of alternative modes of travel, though the general lack of congestion and abundance of six-lane streets could reduce the likelihood of this occurring. Though meeting the community's desire to reduce congestion, this option was rejected due to its high-costs and incompatibility with other community goals and strategies. Preferred Scenario A modified version of the Programmed-Project Option is the preferred scenario based on its multi-modal cost-effective approach to managing increasing transportation demands balanced with other community goals and objectives. The preferred scenario includes Page 18 of 45 Transportation I As Amended 12-10-15 completion of all of the programmed projects. Additionally, the Thoroughfare Plan in the Extraterritorial Jurisdiction must be enhanced to reserve rights-of-way for future needs and promote connectivity. All new and expanded streets must meet the multi-modal objectives of this Plan. Additional funding must be provided for improvements and expansion to the bicycle, pedestrian, and transit systems in the City. Finally it is essential that all streets be designed to enhance their context. FUNCTIONAL CLASSIFICATION Functional classification categorizes streets according to the category's traffic service function they are intended to provide. All streets are grouped into a class depending on the character of traffic and the degree of land access they allow. For the purposes of this Plan streets in College Station are divided into five classes: freeway/expressway; major arterial; minor arterial; collector; minor collector; and local or residential street. Freeways/expressways are intended to carry the highest volumes of traffic for the longest distances with the least amount of direct access. By contrast, local residential streets are intended to carry low volumes of traffic at slow speeds for short distances, offering the highest level of access and connectivity. Functional classification identifies the necessary right-of­ way width, number of lanes, and design speed for the streets. Map 6.6, Thoroughfare Plan -Functional Classification, displays the functional classifications for current and future proposed roadways. COMPLETE STREETS Complete Streets Definition Complete Streets is a relatively new term for an idea from decades past. Long before extensive regulations and requirements that favor rapid automobile movement began dictating street design, streets were built and developed to serve the destinations surrounding them. Some of the greatest streets in America still maintain this centuries-old character. Complete Streets are streets designed for everyone -with safe access for pedestrians, bicyclists, motorists, and transit riders of all ages and abilities. There is no single design for a Complete Street. Each one is unique and should relate to its surrounding community context. This is in contrast to incomplete streets, which are designed with only cars in mind and makes alternative transportation choices difficult, inconvenient, and often dangerous. Complete Streets typically offer many of the benefits that is sought through traditional roadway design: increased road capacity, decreased travel times, and enhanced safety. But it often arrives at these benefits in innovative ways. Typically, road-builders targeted increased roadway performance through the addition of vehicle travel lanes. But with Complete Streets, roadway design might consider Ordinance No. 2015-3729 As Amended 12-10-15 I Transportation enhancing sidewalks or pedestrian crossings, repurposing on-street parking for another mode of travel, or adding a bike lane. Every person who then chooses these other modes of travel is one less driver on city streets, which reduces congestion and extends the service life of the roadway. Context-Sensitive Definition Context Sensitive Solutions (CSS) is taking the goal of Complete Streets and applying it to the process of determining the most appropriate roadway cross sections during construction, reconstruction, or rehabilitation projects. CSS considers many characteristics of a roadway beyond desired functional class to create a realistic and compatible design for the area. These considerations include the context and character of development in an area, future goals for a corridor, and the existing or future need for different modes of transportation. While an acceptable Complete Street may be achieved through the construction of a typical roadway section design, the CSS process should be used to determine if and to what degree the design may need to be changed to achieve the most appropriate section for a corridor. Context-Sensitive Solutions Process Complete Streets projects arise is two basic ways. Many opportunities to implement Complete Street design may occur as part of the construction of new or widened roadways, either as planned capital Improvement projects or private development projects. Other opportunities may arise to retrofit existing roads during a utility-related project or a .minor maintenance project. While there are similarities in how these projects are conducted, the planning processes are different. Capitol projects are roadway and reconstruction projects that are typically placed on the City's capital improvement plan. The scope of these projects is usually large enough to allow for the planning and potential implementation of extensive Complete Streets elements. However, a utility-related project initiated to replace water, sewer, or utility lines may be considered as an opportunity to introduce Complete Streets elements only if the project length is significant. Minor maintenance projects, such as restriping or resurfacing roadways should be evaluated as opportunities to introduce certain Complete Streets elements. Since these maintenance plans can be intermittent based on roadway conditions, they may not be appropriate for full Complete Streets projects, but can still be instances to introduce planned bike facilities or new multimodal features. After determining the type of project, all necessary information should be assembled to best guide the street design process. This information should include both traditional thoroughfare functionality as well as conditions of the surrounding environment. The College Station Thoroughfare Plan should be referenced to identify the roadway functional class and the surrounding context class. The identified context classes include Urban Core, General Urban, Suburban, and Page 20 of 45 Transportation I As Amended 12-10-15 Rural. Some judgment may need to be used to determine the appropriate context class in redeveloping and transition areas. College Station has numerous tools to select an appropriate Complete Street design - a set of typical cross sections, a set of recommended context-sensitive cross sections, and a flexible design guide. During new construction, reconstruction, or widening projects, it should be determined if the typical cross section is most appropriate to achieve the corridor's planned transportation goals. If other travel modes or design elements should be prioritized, then the most appropriate alternative context-sensitive cross sections should be selected. In some cases, constrained right-of-way or reduced pavement width may limit the use of the standard cross section options. In particular, retrofit projects, where multi-modal design elements are being introduced within existing developed areas, may necessitate the development of unique design options. In these scenarios, the flexible design criteria in the design standards toolbox should be referenced to select the essential elements and determine if a design can be adjusted to reduce or eliminate non-vital elements. Ideal cross sections may be difficult to achieve due to constrained conditions. In which case, preferred alternative cross sections would contain as many essential and desired elements as possible. Target Speed Target speed is the highest speed at which vehicles should operate on a thoroughfare in a specific context, consistent with the level of multimodal activity generated by adjacent land uses to provide both mobility for motor vehicles and a safe environment for pedestrians and bicyclists. Historically design decisions are made based on a design speed which is often the posted speed plus 5 mph. The target speed is not set arbitrarily but rather is achieved through a combination of measures that include the following: • Setting signal timing for moderate progressive speeds from intersection to intersection; • Using narrower travel lanes that cause motorists to naturally slow their speeds; • Using physical measures such as curb extensions and medians to narrow the traveled way; • Using design elements such as on-street parking to create side friction; • Minimal or no horizontal offset between the inside travel lane and median curbs; • Eliminating superelevation; Ordinance No. 2015-3729 As Amended 12-10-15 I Transportation • Eliminating shoulders in urban applications, except for bicycle lanes; • Smaller curb-return radii at intersection and elimination or reconfiguration of hig-speed channelized right turns; • Paving materials with texture (e.g., crosswalks intersection operating areas) detectable by drivers as a notification of the possible presence of pedestrians; • Proper use of speed limit, warning, advisory signs and other appropriate devices to gradually transition speeds when approaching and traveling through a walkable area. Source: Designing Walkable Urban Thoroughfares: A Context Sensitive Approach (2010) The Thoroughfare Cross Sections (located at the end of this chapter) provide a preliminary set of design criteria for both the roadside and travelway design. Additional design criteria are provided within the City's Unified Development Ordinance and the Bryan-College Station Unified Design Guidelines. OTHER DESIGN CONSIDERATIONS Context Transitions When planning and designing a context sensitive transportation network, there will be the need to transition between street designs, from time to time. These transitions will most often involve a change in the right-of-way width, number of lanes and the character treatments found in the travelway or the roadside. Transitions may include traditional geometric design changes such as smooth tapers where lanes change and speed limit changes where design speeds change. Transitions in a context sensitive environment extend beyond geometric changes and include multi-modal considerations, as well as visual cues to the change in context. Transitions of these types can indicate that changes in the emphasis on pedestrians, the width of the street, or entering or leaving a special district or corridor. Transitions should, as with all other aspects of the context sensitive design, be guided by the principles found in the American Association of State Highway and Transportation Officials "Green Book," Geometric Design of Highways and Streets, the Manual on Uniform Traffic Control Devices and other approved design guides. Intersections In any street network the design and operation of intersections is significant. In context sensitive design the design and operation of intersections is critical. Multi-modal systems require the safe movement of vehicles, bicyclists, and pedestrians through the intersection. Intersection design encompasses the intersection itself and the Page 21of45 Transportation I As Amended 12-10-15 approaches to the intersection, and may impact adjacent land uses. The Institute of Transportation Engineers publication, Context Sensitive Solutions in Designing Major Urban Thoroughfares for Walkable Communities, identifies the following principles for the design and operation of intermodal intersections: • Minimize conflicts between modes; • Accommodate all modes with the appropriate levels of service for pedestrians, bicyclists, transit, and motorists; • Avoid elimination of any travel modes due to intersection design; • Provide good driver and non-driver visibility ; • Minimize pedestrian exposure to moving traffic; • Design for low speeds at critical pedestrian-vehicle conflict points; • Avoid extreme intersection angles and break up complex intersections with pedestrian refuge islands; and, • Ensure intersections are fully accessible to the disabled and the hearing and sight impaired. As with other design considerations in the context sensitive design approach, accepted engineering guidelines should be used, with the aforementioned principles employed. Minimum Length and Additional Right-of Way for Turn Lanes at Intersections Figure 6.2 illustrates the minimum length for right and left-turn lanes and required right-of-way and at intersections. Table 1 indicates the total length required for turn lane taper, deceleration, and storage by roadway functional class. This is an increase to the current Bryan I College Station Unified Design Standards and is based on NCHRP 780 - Design Guidance For Intersection Auxiliary Lanes. Right-turn lanes are anticipated to be required at all major intersections. Roadway intersections with minor collectors and local streets require engineering judgement to determine if a right-turn lane is required. If it is determined that there are greater than 40 right turns per hour, an additional 14 feet of right-of-way will be required, as indicated in Table 2. Ordinance No. 2015-3729 As Amended 12-10-15 I Transportation Figure 6.2 STREET '2' ' \ - Ec<:EO'RO>(IW><T MINIMUM LENGTH OF RIGHT TURN (Z') Major Arterial 465 FT. Minor Arterial 390FT. j INTERSE:,.ION ROW Z' 1�'1Hr'5£C110flROW Major Collector 255 FT. Minor Collector 200 FT. ln:noti.rn:; u1o;i. IU(.111 TVllU lf�"lt:} -r-1-... local 200 FT. Table 1 STREET ROW REF: TABLE IV REQUIRED RIGHT-OF-WAY WIDTH AT IN TERSECTIONS· (X') Major Arterial 144' 144' 144' 144' I 130' (144') Minor Arterial 119' 119' 119' 119' '105 (119') STREET 'l' Major Collector 94' 94' 94' '80' (94') *80' (94') Minor Collector 74' 74' '60' (74') '60' (94') '60' (94') Major Arterial Minor Arterial Major Collector Minor Collector Local STREET '2' •-STUDY TO DETERMINE IF A RIGHT TURN LANE IS REQUIRED. IF REQUIRED, AN ADDITIONAL 14' Of ROW WILL BE REQUIRED AS SHOWN IN ( ). Table 2 Other Design Components In context sensitive design, consideration should be given to a number of design components that respond to the multi-modal nature of the system. These include, but are not limited to, access management and the placement and design of cross-walks, bus stops, curb extensions, and pedestrian refuges. The Institute of Transportation Engineers publication, Context Sensitive Solutions in Designing Major Urban Thoroughfares for Walkable Communities, and the various American Association of State Highway and Transportation Officials guidance documents should be consulted tor the proper and safe application of each of these components. Right-of-Way for Utilities Additional right-of-way may be dedicated to provide a location for the installation of water, sewer, gas, electric power, telecommunications and other similar services and utilities. An additional l O' beyond each streetside area may be dedicated to allow for such utility installation. Page 24 of 45 Transportation I As Amended 12-10-15 Rehabilitation Projects and Neighborhood Street Network Much of this chapter has focused on the design and construction of new streets. In a number of instances, improvements may be necessary within established neighborhoods, involving either rehabilitation projects or possibly even new street construction. While the guidance provided in this chapter should serve as a foundation for projects in established neighborhoods, it is necessary to recognize the sensitivity of such projects. Projects in such areas often have to address constrained rights-of-way, the presence of mature vegetation, and resident preferences. It is proposed that, where possible, the identification of and design for projects within established neighborhoods be guided by the neighborhood plan and direct public input unique to each project. A similar process is appropriate for the districts and corridors identified in the Future Land Use & Character map contained in this Plan. Primary Mobility Corridors The context sensitive solutions approach outlined in this chapter focuses primarily on arterials and collectors, due to their role in the transportation network and ability to serve multiple modes of travel. Streets classified as freeways or expressways serve primarily to move vehicles through the City and between distant locations within the City. State Highway 6 and sections of Raymond Statzer Parkway (FM 60), William D. Fitch (State Highway 40), and Harvey Mitchell Parkway (FM 2818) are examples. For the purposes of this Plan, these streets are considered primary mobility corridors. While it may be possible that these corridors be designed to handle pedestrians and bicyclists, in general they will be designed to accommodate high volumes of vehicular traffic at high speeds (usually in excess of 45 mph). These corridors can also carry transit vehicles, though they are not likely to provide transit stops. Alternative parallel routes should be identified to accommodate the modes of travel that the primary mobility corridors cannot. The design of these corridors should be guided by their own unique requirements (both mobility and access and other contextual needs) and should include direct public input unique to each project. Right-of-Way Constrained Projects From time to time, the right-of-way for a public street project will be constrained due to a natural constraint, such as floodplain, or because of the proximity of existing development. In such instances, it is necessary to evaluate what can and cannot be accommodated within the available right-of-way. This evaluation should be guided both by the vehicular needs and the context of the street. A uniform process should be developed incorporating a "decision-matrix," such as the example shown in Figure 6.3, College Station Context Sensitive Design Process, will aid decision makers in implementing context Ordinance No. 2015-3729 As Amended 12-10-15 I Transportation sensitive solutions. In some contexts it may be appropriate to eliminate parking lanes to accommodate wider sidewalks or planting areas. In other contexts it may be appropriate to use narrower sidewalks to accommodate both parking lanes and bicycle lanes. In still other contexts it may be appropriate to eliminate a travel lane or alter the design of travel lanes to accommodate parking lanes. Identify Surroundi ng Context Zone Some judgment may need to be used in transition areas � Select Appropriate Cross Section from the Available Options If ROW is available, build from the Cross Section Guide GOAL, STRATEGIES, AND ACTIONS College Station strives for improved mobility through a safe, efficient, and well-connected multi-modal transportation system designed to be sensitive to the surrounding land uses. Five strategies have been developed to progress toward this goal. Each strategy has a series of action recommendations designed to implement the related strategy. Strategy 1: Develop, implement and maintain, through regular review, a mufti-modal transportation plan that supports the planned growth and development pattern. • Thoroughfare Plan. Adopt and implement the Thoroughfare Plan. • Future Planning. Amend the Thoroughfare Plan as necessary as neighborhood, district, corridor, and master plans are adopted by the City. Page 25 of 45 Ordinance No. 2015-37 9 Page 26 of 45 Transportation I As Amended 12-10-15 • Project Programming. Maintain and amend as necessary the City's various programs (Bryan-College Station Metropolitan Planning Organization Transportation Improvement Program, Capital Improvements Program, etc.) used to fund projects. • Monitor Trends. Continue to collect and monitor transportation data including vehicle miles traveled, traffic counts, levels of service, transit ridership, and pedestrian and bicycle facility usage, crashes. • Context Sensitive Solutions. Amend as necessary, the various tools used to implement the Thoroughfare Plan to ensure context sensitive solutions are employed. These include the Unified Development Ordinance, the Bryan-College Station Unified Design Guidelines, and the City's project development process. Strategy 2: Reduce and manage traffic congestion. • Thoroughfare Plan. Adopt and implement the Thoroughfare Plan. • Monitor Trends. Continue to collect and monitor transportation data including vehicle miles traveled, traffic counts, levels of service, transit ridership, and pedestrian and bicycle facility usage, crashes. • Access Management. Promote access management strategies where appropriate to preserve modal efficiency throughout the thoroughfare system. • Traffic Control Technology. computerized traffic control synchronization. Install a state-of-the-art system including signal • Travel Demand Management. Develop and implement a travel demand management program including real-time traffic information, traffic incident alerts, ridesharing programs, promotion of flexible work schedules, and encouragement of dense mixed-use development. • Intersection Improvements. Continue enhancements and upgrades at intersections to improve multi-modal efficiency. Strategy 3: Develop and implement context sensitive transportation solutions. • Thoroughfare Plan. Adopt and implement the Thoroughfare Plan. • Future Planning. Amend the Thoroughfare Plan as necessary as neighborhood, district, corridor, and master plans are adopted by the City. • Context Sensitive Solutions. Amend, as necessary, the various tools used to implement the Thoroughfare Plan to ensure context sensitive solutions are employed. These include the Unified Development . Ordinance, the Bryan-College Station Ordinance No. 2015-3729 As Amended 12-10-15 I Transportation Unified Design Guidelines, and the City's project development process. • Bicycle and Pedestrian Planning. Amend and implement the bicycle and pedestrian system master plans. • Transit. Pursue opportunities with the current transit providers to expand and enhance transit services within and between activity centers and dense residential areas, concentrations of student housing, etc. • Project Programming. Maintain and amend as necessary the City's various programs (Bryan-College Station Metropolitan Planning Organization Transportation Improvement Program, and Capital Improvements Program) used to fund projects. • Primary Mobility Corridors. Adopt and implement the context sensitive approach identified in this Plan for identified primary mobility corridors. • Rehabilitation Projects. Adopt and implement the context sensitive approach identified in this Plan for rehabilitation projects located within established neighborhoods or districts. • Right-of-way Constrained Projects. Adopt and implement a context sensitive approach and decision matrix for City projects where the available right-of-way is constrained. Strategy 4: Promote and invest in alternative transportation options. • Thoroughfare Plan. Adopt and implement the Thoroughfare Plan. • Future Planning. Amend the Thoroughfare Plan as necessary as neighborhood, district, corridor, and master plans are adopted by the City. • Context Sensitive Solutions. Amend, as necessary, the various tools used to implement the Thoroughfare Plan to ensure context sensitive solutions are employed. These include the Unified Development Ordinance, the Bryan-College Station Unified Design Guidelines, and the City's project development process. • Bicycle and Pedestrian. Amend and implement the bicycle and pedestrian system master plans. • Transit. Pursue opportunities with the current transit providers to expand and enhance transit services within and between activity centers and dense residential areas, and concentrations of student housing. • Project Programming . Maintain and amend as necessary the City's various programs (Bryan-College Station Metropolitan Planning Organization Transportation Improvement Program, and Capital Improvements Program) used to fund projects. • Commuter Rail. Continue to participate in the Texas High Speed Rail Initiative and similar efforts to bring commuter rail services to the City. Ordinance No. 2015-37 9 I Page 28 of 45 Transportation I As Amended 12-10-15 Strategy 5: Balance changes in land use with the capabilities of the transportation system. • Use of Future Land Use & Character Map. Adopt and implement the Future Land Use & Character map contained in this Plan. • Land Use and Development Review. Continue to evaluate the capacity of the existing and proposed transportation system in Comprehensive Plan amendments, rezoning requests, and site plan reviews. • Traffic Impact Analysis. Require traffic impact analyses for all development proposals anticipated to generate significant volumes of traffic. • Monitor Trends. Continue to collect and monitor transportation data including vehicle miles traveled, traffic counts, levels of service, transit ridership, and bicycle and pedestrian facility usage, crashes. ''--"\<;) <��'j / .. \, \. / ':�� / ; '� i� �:-j" \- ·,, ....... '--�. I'·". !' ......... >/ K("( (' ' 7 ·/ / /·,, . \ Xv'\ ) ('•< ·�;-." -<.,; '\ \ '�·-..... , ·· .. ,"' :-..., \, \ ,.1. '\ y.____ _ _,�1 /' � '-� _,/" --/'( L.P'�j ' r \ ---�/� :t---' ' . ) \ -� ' _A,, \..___ ( '-;/"._, /\,// '\ I'\ ' \ \ \ ,, '-..,_ 0 025 0.5 Mo"'s ' Source: Kimley�Horn ;>f "';�·,. "• ,_, ' -'., .... � -X .. ), -'· .,.; ... ;�"., / >-.....--.....>-........__ /. ( \ ' .>� ... .. '····-.....,," / '-, ..,. /''--.... " ? '·,, \__..; r- /) ,/ /'"'/' .. '',.(J .,, ... ,, ....... , ..... \ \ \ '' .... "-.... ..... , / . .,, '\ /\(""--! \,\ �, June 201 Map 6.1 Existing Traffic Volumes Avg. Daily Traffic -0-5,000 -5,001 -15,000 -15,001 -25,000 -25,001 -40,000 -40,001 -65,000 -65,001 -109,195 ..r-':'J City Limits ""oJ ETJ -+--+ Railroad Grr--- CJn-OF COLLEGE STATION Kimley)» Horn .1 ('I -0 a. 0 :E ··. •,G __ Cl> u ·s: .... Cl> CD V) :a CD .i9 -:a 0 Q_ � CD " CD " j2 Cl> <{ > Cl> ..... l.O .- 0 ('I CD :a .i9 Q_ CD " 'E " 1J ro ::::; 0 c � :::> .i':' 0 iii 0 "' L. :, ...r + ..• ••• •••I() � �-.-----1� ll) M 0 N c:: U) Q) c:: ca ...J N 'i" <O I I I 'E :::; .c 0 L :., :...r •••••••• .,.,, •• ,,,,,,,. .•••.•...... ,,,, •• ,,,, •••• ,, If) iii ��, !'"-. ---,, . \.\ .... ""''>"/"\.,_ \ ,r·� \ ' /' ' , /''< ·�;\.\ "'-, '•,, .,_, \\ \. ,:c.,. ,_.../ """,. l., \ � !< --:i_f---.., .• .. ' i\ ....--_,..--,. ....... / / \ ' ' \ ("' \......_ {\ '----y·,, /'�v/ \ ,,/ \ \,\,'- \ (I (I� l'.5 1 w -· ' Source: Kimley�Horn \"-........ ') September 2015 Map 6.5 2035 Traffic Volumes with Programmed Projects Avg. Daily Traffic -0-5,000 -5,001-15,000 -15,001 -25,000 -25,001 -40,000 -40,001 -65,000 -65,001 -114,000 l "':°.i City Limits � .. ETJ -+--+ Railroad c.:r� C!w OF COLLEGE STATION Kimley)» Hom > .. .,"-.../"-., >l� '/ . ·�· 2 � " ! 11 �·�_/� . -�-� .. �-·"" , ··�·;· I I � .. /'4 WS�!8 I Source: Kimley-Horn Map 6.6 Functional Classification and Context Class Thoroughfare Plan Functional Classification -Grade Seperation -Freeway/Expressway -6 Lane Major Arterial = 4 Lane Major Arterial ==== 4 Lane Minor Arterial -2 Lane Major Collector = 2 Lane Minor Collector Context Zones Context -UrbanCore -General Urban Suburban Rural ,.r-'] City Limits "'";.J ETJ -+-+ Railroad c.:r-- Ctw OF COLLEGE STATION Kimley)» Horn '"> !.. \, // r�· 0-, __ // ;/ (' �- K , .... -,,, "·�r·� ,,-...., ... K" '\ - ) ·--/\ \ \ \ �-­ \� /�\ '\.-/ \ "·\ ... ,\ .. -.... Source: Kim!ey-Horn '·.J ""·,j i September 201 Map 6.7 Future Level of Service -Acceptable Tolerable Unacceptable ,s'] Citylimits "":.1 ETJ -+-+ Railroad ,r� • CiW OF COLLEGE ST..\TION Kimleyl>) Horn Ordinance No. 2015-3729 EXHIBIT B Page 35 of 45 Thoroughfare Cross Sections Typical Sections City of College Station Note: All dimensions measured from back-of-curb and center of stripe. • Sidewalk 6' Travel Lane Travel Lane Travel Lane 12.5' 12' 12.5' t------�37'--------< Major Arterial Median 21' I_ Travel Lane Travel Lane Travel Lane 12.5' 12' 12.5' 1-------37-' ------! Shared-Use Path 12' t----------------------130'---------------------1 Sidewalk 6' Bike Lane Travel Lane Travel Lane 6.5' 2' 12' 12.5' f-------33'------{ Minor Arterial Median 17' Travel Lane Travel Lane Bike Lane 12.5' 12' 2' 6.5' 1------33'--------< Sidewalk 6' 1-------------------105'------------------! ••••••••••••••••••••••••• Kimley»>Horn Ordinance No. 2015-3729 Page 36 of 45 Thoroughfare Cross Sections Typical Sections City of College Station Major Collector • Sidewalk Bike Lane Travel Lane TWLTL Travel Lane Bike Lane Sidewalk 6' 6' Sidewalk 6' 2' 12' 14' 12' 54' 80' Minor Collector Bike Lane Travel Lane 7' 12' Travel Lane Bike Lane 12' 7' 2' 1------�38'-----------< 6' Sidewalk 6' 1----------�60'---------------i Open Ditch 4:1 Slope Maximum � (_) "' 0 -0 -0 ______ .,.&: 28' 2' Rural Collector Travel Lane Travel Lane 16' 16' -0 "' (_) "' 0 -0 -0 Open Ditch 4:1 Slope Maximum c;: _____ _ 2' 28' 1-------36'----------< 1-------------90'------------------< 6' ••••••••••••••••••••••••• Kimley»>Horn Ordinance No. 2015-3729 Page 37 of 45 Thoroughfare Cross Sections Major Arterial City of College Station Note: All dimensions measured from back-of-curb and center of stripe. • Sidewalk 6' • Sidewalk1 15' Typical Section '-·-"1 Travel Lane Travel Lane Travel Lane Median Travel Lane Travel Lane Travel Lane 12.5' 12' 12.5' 21' 12.5' 12' 12.5' 37' 37' 130' Urban Core Bike Lanes, Wide Sidewalks @ r..�.'1 Bike Lane Travel Lane Travel Lane 6.5' 2' 11' 11.5' >------31 -' -------< Median 17' -- • Travel Lane Travel Lane Bike Lane 11.5' 11' 2' 6.5' t------31'--------l Shared-Use Path 12' • Sidewalk1 15' 1---------------------1 20'1 ___________________ ___, 1) Sidewalk width to vary depending on available right-of-way. ••••••••••••••••••••••••• Kimley»>Horn I I I I I ·1 Ordinance No. 2015-3729 Page 38 of 45 Thoroughfare Cross Sections Major Arterial City of College Station Sidewalk 6' Wide Sidewalk 10' Travel Lane Travel Lane Travel Lane 11.5' 11' 11.5' 34' Travel Lane Travel Lane Travel Lane 11.5' 11' 11.5' General Urban Shared Use Path Median 17' 130' Suburban Wide Sidewalks Median 17' 1------34'-----� Travel Lane Travel Lane Travel Lane 11.5' 11' 11.5' 34' -- ,•--•, Travel Lane Travel Lane Travel Lane 11.5' 11' 11.5' >------34'------l Shared-Use Path 12' Wide Sidewalk 10' f----------------------130'---------------------l ••••••••••••••••••••••••• Kimley»>Horn Ordinance No. 2015-3729 Page 39 of 45 Context-Sensitive Cross Sections Minor Arterial City of College Station Note: All dimensions measured from back-of-curb and center of stripe. Sidewalk 6' Bike Lane Travel Lane Travel Lane 6.5' 2' 12' 12.5' t---�--33'------i Typical Section Median 17' tJrban Core Travel Lane Travel Lane Bike Lane 12.5' 12' 2' 6.5' t------33'-------I Bike Lanes, Wide Sidewalks Median orlWLTL Sidewalk 6' Sidewalk Bike Lane Travel Lane Travel Lane Travel Lane Travel Lane Bike Lane Sidewalk 16.5' Sidewalk 6' 6.5' 2' 10.5' 11' 12' 11' 10.5' 2' 6.5' 30' 30' 105' General Urban Bike ILanes -- Bike Lane Travel Lane Travel Lane Turn Lane Travel Lane Travel Lane Bike Lane 6' 2' 11' 11' 12' 11' 11' 2' 6' 16.5' • Sidewalk 6' t-------------72'-----------------< t------------------105'-------------------i ••••••••••••••••••••••••• Kimley»>Horn '-j ·1 Ordinance No. 2015-3729 Page 40 of 45 Context-Sensitive Cross Sections Minor Arterial City of College Station • Sidewalk 6' Sidewalk 6' Travel Lane Travel Lane 11.5' 11.5' General Urban/Suburban Shared,.t.Jse Sidepath Median 17' Travel Lane Travel Lane 11.5' 11.5' 1----23'-----< 1----23'----< Suburban Bike Lanes Bike Lane Travel Lane Travel Lane Median Travel Lane Travel Lane 5.5' 2' 11' 11.5' 17' 11.5' 11' 30' 30' 105' Shared-Use Path 12' Bike Lane Sidewalk 2' 5.5' 6' ••••••••••••••••••••••••• Kimley»>Horn I I I Ordinance No. 2015-3729 Page 41of45 Context-Sensitive Cross Sections Major Collector City of College Station Note: All dimensions measured from back-of-curb and center of stripe. • Sidewalk 6' Bike Lane Travel Lane 6' 2' 12' Typical Section lWLTL 14' Travel Lane Bike Lane 12' 2' 6' 1----------54'-----------I Sidewalk 6' 1---------------80'---------------l Sidewalk 14' Urban Core Bike Lanes, Parking Bike Lane Parking Travel Lane Travel Lane Parking Bike Lane 5.5' 3' 7' 10.5' 10.5' 7' 3' 5.5' t----------52'--------� Sidewalk 14' 1---------------80'---------------l Sidewalk 6' Bike Lane Travel Lane General Urban Bike Lanes lWLTL Travel Lane Bike Lane 6.5' 11' 11' 6.5' 14' 1---------49'--------i Sidewalk 6' t---------------80'--------------{ ••••••••••••••••••••••••• Kirnley»>Horn Ordinance No. 2015-3729 Page 42 of 45 Context-Sensitive Cross Sections Major Collector City of College Station Sidewalk 6' Sidewalk 6' General Urban/Suburban Bike Lanes, Median Bike Lane Travel Lane Median Travel Lane Bike Lane 5.5' 2' 11.5' 16' 11.5' 2' 5.5' 1----19'------1 1----19'-__ ___, Suburban Bike Lanes, Parking* ---- *Parking may be located on either side of bike lane Bike Lane Parking Travel Lane Travel Lane Parking Bike Lane 5.5' 3' 7' 10.5' 10.5' 7' 3' 5.5' 1----------52'--------� Sidewalk 8' Sidewalk 6' 1-------------�80'--------------l ••••••••••••••••••••••••• Kimley»>Horn Ordinance No. 2015-3729 Page 43 of 45 Context-Sensitive Cross Sections Minor Collector City of College Station Note: All dimensions measured from back-of-curb and center of stripe. Typical Section Sidewalk Bike Lane Travel Lane Travel Lane Bike Lane Sidewalk 6' 7' 12' 12' 7' 6' 1--------38'---------l 1-----------60'------------l Urban Core Bike Lanes t Sidewalk Bike Lane Travel Lane Travel Lane Bike Lane Sidewalk 12' 5.5' 2' 10.5' 10.5' 2' 5.5' 1-------36'-------l 12' >------------60'-------------i General Urban Bike Lanes Sidewalk Bike Lane Travel Lane Turn Lane Travel Lane Bike Lane Sidewalk 8' 12' 1--------�44'----------i 6' 10' 10' 6' 8' 1-----------60'-------------i ••••••••••••••••••••••••• Kimley»>Horn Ordinance No. 2015-3729 60' 38' 12' 11' S tandard N/A None None None 6' 7' N/A None 30 5' Permitted Minor Collector 60' 36' 10.5' 12' Standard N/A None None None 10' 5.5' N/A 2· None 25 N/A N/A 60' 44' 10' 8' Standard N/A 12' None None 6' 6' N/A None 25-30 N/A NIA 60' 38' 12' 11' Standard N/A None Optional (7') None 6' 7' N/A None 25-35 N/A N/A 80' 54' 12' 13' Standard N/A 14' None None 6' 6' 2· None 35 6-10' Permitted Minimum Geometric Design Criteria for New Construction Major Collector 80' 80' 52' 49' 10.5' 11' 14' 15.5' Standard Standard N/A N/A Optional (11 ') 14' Optional (7') None None None 10' 6' 5.5' 6.5' N/A 3· Optional (2') None None 25-30 25-30 6' 6-10' Permitted Permitted 80' 38' 11.5' 13' Standard N/A None None 16' 6-8' 5.5' 2' None 25-30 6-10' Perrnined 80' 52' 10.5' 14' Standard N/A None Optional (7') None 6' 5.5' 3' None 25-30 5' Permined 105' 66' 12' 11' Standard N/A None None 17' 6' 6.5' 2' None 40 5' Permitted Minor Arterial 105' 60' 10.5' 16.5' Standard N/A Optional (12') Optional (7') Optional (12') 10· 6.5' 2' None 25-35 6' Permitted 105' 72· Undivided 46' Divided 11' 16.5' Undivided 21' Divided Standard N/A 12' None Optional (17') 6' 6' Lanes or 12· Sideoath 2· 12' 30-40 6-8' Permitted 105' 60' 11' 14' Standard N/A None Optional (7') 17' 6' 5.5' 2· None 30-40 6-8' Permitted Page 45 of 45 Major Arterial 130' 120· 130' 130' 74' 62' 68' 68' 12' 11' 11' 11' 17.5' 20.5' 22.5' 22.5' Standard Standard Stan dard Standard N/A N/A N/A N/A None None None None None Optional (7') None None 21' 17' 17' 17' 6' 10' 6' 6' None 6.5' None None N/A 2' N/A N/A None None 10-12' 10-12' 45 30-35 40-45 40-45 6-8' 6-10' 6-12' 6-8' Perrnined Permitted Permitted Permitted