Aerospace Technology Magnet School, grant

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1?3 .(U'/,tz ,Los- JJ a,4v:t'?)Q_ ( 1 \0-,& ~~ 9tv( ~~ vvlCvt,1.- FRIDAY, ELDREDGE &. CLARK HERSCHEL H. FRIDAY , P.A. ROBERT V . LIGHT . P. A . WILLIAM H . SUTTON, P. A . JAMES W. MOORE A PARTNERSHIP OF INDIVIDUALS AND PROFESSIONAL ASSOCIATIONS ATTORNEYS AT LAW BYRON M . EISEMAN. JR . , P. A . JOE 0. BELL , P.A. JOHN C . ECHOLS . P.A. JAMES A . IUTTRY, P. A . FREDERICK. 8 . URSERY . P. A . H . T. LARZELERE, P. A. OSCAR E. DAVIS , JR. JAMES C. CLARl, JR . , P . A . THOMAS P. LEGGETT, P. A . JOHN DEWEY WATSON , P.A. PAUL B . IENHAM Ill, P. A . LARRY W. IURlS, P.A . A . WYClllFF NISIET , JR. , P.A. JAMES EDWARD HARRIS , P. A . J . f"HILLIP MALCOM. P. A . JAMES M . SIMPSON, P .A. MEREDITH P. CATLETT, P .A. JAMES M . SAXTON, P.A . J . SHEPHERD RUSSELL 111 DONALD H . IA.CON, P. A . WILLIAM THOMAS BAXTER , P. A . WAL TEA A. PAULSON II , P. A . BARRY E. COl"LIN, P . A . RICHARD D. TAYLOR, P' . A . JOSEPH 8 . HURST, JR . , P . A . ELIZABETH J . ROBBEN, P. A . CHRISTOPHER HELLER , P. A . LAURA HENSLEY SMITH, P . A . ROBERTS. SHAFER, P.A. WILLIAM M . GRIFFIN Ill , P.A . THOMAS N . ROSE , P . A . MICHAEL S MOORE DIANE S MACKEY , P . A WAL TER M EB EL Ill . P .A 2000 FIRST COMMERCIAL &UILDINQ 400 WEST CAPITOL LITTLE ROCK, ARKANSAS 722013413 TELEPHONE 1501-378-2011 FAX NO. 601-378-2147 December 7, 1992 The Honorable Susan Webber Wright United States District Judge Post Office & Courthouse 600 West -Capitol Little Rock, AR 72201 DEC 9 1~2 IC.EVIN A. CRASS. P.A . WILLIAM A . WADDELL, JR . , P. A . CLYDE TA. TURNER, P.A . CALVIN J . HALL, P. A . SCOTT J . LANCASTER, P.A . JERRY L . MALONE, P. A . M . GAYLE CORLEY . P. A . ROBET I . IEACH, JR . P' . A . J. LEE IROWN, P . A . JAMEi C . IAI.ER, JR . , P' . A . H. CHARLES GSCHWEND, JR ., P.A . HARRY A . LIGHT, P'.A . ICOTT H . TUCKER JOHN CLAYTON RANDOLPH GUY Al TON WADE PRICE C . GARONER THOMAS F . MEElS J. MICHAEL PICKENS TONIA P. JONES DAVID D . WILSON JEFFREY H. MOORE T . WESLEY HOLMES ANDREW T . TURNER SARAH J . HEFFLEY JOHN RAY WHITE DAVID M. GRAF PAMELA D . CORKER CARLA G . SPAINHOUR JOHN C . FENDLEY , JR. COUNH WILLIAM J . SMITH WILLIAM A . ELDREDGE , JR. , P. A . 8 . S . CLARl WILLIAM L. TERRY WILLIAM L. PATTON , JR ., P. A . WII I TUI' OUUCT NO. 15011 370 - 1506 D Re: LRSD v. PCSSD Office of Desegregation Monitoring Dear Judge Wright: I am writing to provide a status report concerning LRSD's efforts to secure a grant to establish an Aerospace magnet school. The LRSD Board of Directors has adopted a resolution to establish such a school subject to the following conditions: 1. That the district receives from the Magnet School Assistance Fund Grant a minimum of $8,000,000.00 over a two year term
2. that funds to defray the cost of operating the school will be obtained from public or private sources for a period of five years beginning with the date the school opens. Construction will begin when the five year commitment of operating funds is identified
3. that the district can demonstrate to the Court that the school will compliment its desegregation plan and receive approval from the Court to modify its plan to include the construction and implementation of the Aerospace school. Al though the board voted to pursue the grant subject to these conditions, several members made it clear that they would vote to reject the grant if, at the time the grant is announced, it appears that sufficient funds are not available for LRSD to effectively implement its desegregation plan, meet its other obligations and establish the Aerospace magnet school. Finally, I have been informed by grant writer Gail Quinn that the deadline for the grant application will probably be extended to early February. I do not yet have a final grant application to share with the Court and the parties, but I will provide one as soon as it is completed. CJH/k cc: All Counsel Ann Brown Gail Quinn *** ****************************************************************************************************** P.01 * * TRANSACTION REPORT * * ------- DEC- 8-92 TUE 14: 33 * ** DATE START SENDER RX TI ME PAGES TYPE NOTE ** * ---------------------------------- * * DEC- 8 14:31 501 324 2032 11 39" 2 RECEIVE OK * * * ************** ***************************'************************************************************* 12 / 08 / 92 15:J '6'501 324 2032 LR School Dist OD~ ..-~ LITTLE ROCK SCHOOL DISTRICT DATE TO FROM SENDER'S PHONE# SUBJECT Special Instructions 810 WEST l\1/\RKHAM STREET LITTLE ROCK, AR 72201 FAX (501) 324-2032 ~ ~ 1 141001 / 002 Number of Pages (incluM cover page) j__ Fax Phone Number___ Speed dial r__..---- FOR COMMUNICATIONS OFFICE USE ONLY Transmitted By ---------Date --------Time ---- 12/ 08/ 92 15 : 44 '0'501 324 2032 LR School Dist ODM December 8, 1992 TO: Ms. Ann Brown Mr. Dick Holbert Mr. Chris Heller FROM: Mac Bernd, Superintendent of School~ SUBJECT: MAGNET SCHOOLS ASSISTANCE GRANT FOR AEROSPACE SCHOOL l4J 00 2/002 To keep you updated on the status of the grant application, you need to know that we received a telephone call yesterday from Gail Quinn explaining that she is having problems getting the grant application printed and will possibly be required to re-format to another computer program. She was optimistic, however, that she would be able be overnight mail the grant last evening. We have not talked with her this morning and have not yet received the grant. cc: Board of Directors DEC 9 19Y2 Office of Desegregation Monitoring Little Rock School District Aerospace Technology Magnet Program Ahsb.-.t The Little Rock Schoo District's Magnet Schools Assistance grant applicatia, presents a dynamic plan fer implementation of a grade 7-12 Aera
pace Techndogy Magnet Program in three (3) junior high schoos and the new Aera
pace Educatia, Center. The Center combnes a museum of aviatia, histcry with a grade 7-12 Aera
pace Technology Schoo oo a 19.8 acre tract at the Little Rock Regirnal Airpai adjacent to the main terminal, Falcoo Jet, and Arkansas Aerospace. Collabcratively develc.ped with the Aerospace industnesi> and Campaign Leadershipb>, foor universitiescl and the U.S. Department ci Educatirn Federal Aviatia, Administratia, (FAA), this magnet program targets the readying of students fer immediate employment and/er postsecondary education in either engineering technology er aitway science. As illustrated belON, students are prCNided a wide range ci choices fer career develc.pment in ooe of nine areas at an entry, technician, er prdessiaial level: Aerospace Engineering Technology Aviation Airway Science ( FAA) Manufacturing Airway Canputer Science Computer Science Airway Science Management Mechanical Aircraft Maintenance Electronics Aircraft Systems Professiooal Pilct Majer Arkansas aeraspace employers and the FAA have identified tec:hndogical ocaJpatioos and the skill base students need for future employment. LRSD has incrnpcrated the skill base into a highly integrated program/cairse sequence coosisting ci Academic lnstructioo, Work-Based Leaming, Wcrksite Experience, and Information and Guidance. All magnet students will take a a:mmrn academic ccre of sequenced cairses which include six years ci applied mathematics and science (mcre than required for graduation) keyed to prcxiuct engineering and flight/space ooncepts, two cr more years d a language significant to oor global a:mpetitive marketplace such as Japanese er German
and Applied Canmunication. In c:anputer netwcrked laboratcries, students will access and a:ntrd content, applicaticns, and infamatirn in the areas ci rcbotics, bio astronautics, systems simulatioo, CAD/CAM, publishing, wcrd proces.sing, teleccmmunicatirns, material science, and aerodynamics. Students will produce presentatioo material by importing soond, graphics, digitized phctographs to hypercard er laserdisc stacks ci their c,,vn creatioo. In Scien~ students wilt cooduct hands-on investigatirns, manipulate scientific instruments, and cdlect/ analyze data a) Arkansas Aerospac~ Rohr Industries, Falcon Jet, Midcoast, Ce,tral Flying Servic:2 b) Membership attached c) l 'niversities of Arkansas at Little Rock and Pine Bluff, He,derson State University, Southern Arkansas University TECH. using the critical thinking skills d observatirn, canmunicating. cnmparing. a-deting. categotizing. relating. inferring. and applying. Specialized curricula related to each d the nine career cptia,s has been developed to meet ocrupation specific kno.vledge and emerging techndogy requirements. Students will be trained on the job throogh partidpatioo in industry and airpa-t-based internship programs. All students will be educated to higher levels than ever befae. The vehide for cx:::aipaticnal artificaticn is achievement d the U.S. Department of Labcr's SCANS (Secretary's Canmissicn d Achieving Necessary Skills) five workplace canpetendes, e.g. Resources, Interpersaial Skills, lnfa-mation, Systems, and Technology
and the earning of c.ertificate3 d Initial Mastery (CIM). An assessment system based a, SCANS Kno.v-Ho.v and cumulative re3ume, which reports re3ults, will be the permanent reccrd ci genuine student attainment of CIM and future employment. In addition, program ccmpletion in a chosen cx:cupaticnal maja will enat:ie students to receive advance university credit and cootinuatia, of the engineering a airway science career track thrcugh associate ci science and baccalaureate degree programs. As ycu c:cnsider the fine merits of this highly cdlabJrative magnet progrc3Jl\ please keep in mind the thcusands a students it will enable to gain state-of-the-art techndogical ski11s, enoourage to cootinue their education thraigh Artla.ilatta, Agreements, and to fill key manufacturing and FAA jd:ls so vital to the future a this nation to ccmpete in the wald market. Student Progression in the Aerospace Technology Magnet "Linking the Curricular Path to Work" Level 1- Aerospace Education Center Grades 7-12 Engineering Technology or Airway Science & Professional Pilot Level II - Advanced & Specialized Training Southern Arkansas University TECH - Associate of Applied Science Degree and/or Advanced Certificates (one year after Associate Degree) ..ar.. -Aviation Maintenance __,,.. UALR - Electronics Engineering Technology - Mechanical Engineering Technology Level Ill - Baccalaureate Programs UALA - Manufacturing Engineering - Computer Engineering Henderson State University .. - Aircraft Systems Management - Professional Pilot - Airway Science Management - Airway Computer Science Entry-Level Employment Support Analyst Quality Analyst CAD Operator Hazardous Material Specialist Technical Careers , Associate Engineer Tool Designer Quality Technician Hazardous Material Team Leader Professional Careers Production Engineer Manufacturing Engineer Liaison Engineer Design Engineer Quality Engineer Environmental Engineer I. Background Information A. Greater Metropolitan Little Rock Greater Little Rock's four county Metropolitan Statistical area (MSA) is the center of the second fastest growing region in the United States. Its central location is within 550 miles of forty percent of the United States buying power and population. The $1.3 billion dollar Arkansas Navigation System, one of the nation's largest water development projects, is a 445 mile waterway providing year-round access to ports on the Arkansas River from the Mississippi River to Tulsa, Oklahoma. The 1,500 acre port with its industrial harbor Foreign Trade Zone -14, and the United States Customs Port of Entry are an indication of the increasing importance of Little Rock's linkage to ports worldwide. All are in close proximity to Adams Field, Little Rock's airport. The city's rich mixture of historic architecture and new development is attracting new residents. Little Rock is seeing growth and revitalization unparalleled in the city's history. Little Rock is on the move. Fueling this revitalization are the aerospace industries, the Arkansas Aviation Historical Society, the Governor's Aerospace Task Force, and institutions of higher education. Some of the world's most successful aerospace companies are located here: McDonnell Douglas, Rohr Inc., Arkansas Aerospace (a subsidiary of British Aerospace), Falcon Jet owned by the French-based Avions Dassaut Brequet Aviation, MidCoast, and Central Flying Service. Numerous private and corporate aircraft dealers such as Aero-Commander, Piper, Beechcraft, and Cessna have facilities at the Little Rock Regional Airport. Little Rock Airforce Base is home to the largest C-130 aircraft training and airlift facility in the world. A number of major educational institutions serve Little Rock's M.S.A. By far, the largest of these is the University of Arkansas at Little Rock (UALR), enrolling more than 11,000 students in seventy-five undergraduate and forty-two graduate degree programs including Associate, Bachelor and Masters of Science Degrees in Engineering Technology. The Graduate Institute of Technology (GIT) housed in the new Engineering Technology Center offers courses in mechanical, computer science, electrical and manufacturing engineering. Industries utilize GIT facilities for advanced research and graduate study. In 1991, the Arkansas Space Grant Consortium, under the leadership of GIT at UALR, received a four-year training grant award from the NASA National Space Grant College and Fellowship program. The primary purpose of the program is to educate and familiarize faculty and undergraduate and graduate students with aerospace fundamentals and NASA's research programs and opportunities. A secondary objective is to motivate K-12 students to excel in math and science courses necessary for entrance into aerospace programs at the universities and high tech positions in industry. Henderson University, in coordination 1 with Central Flying Service, conducts one of the few aviation degree programs in the nation. The University's Department of Aviation provides four-year programs in Airway Science Management, Airway Computer Science, Professional Pilot, and Aircraft Systems Management. The Arkansas Aviation Historical Society serves the entire state as the focal for the involvement of Arkansas' aerospace industries in community affairs, education, and economic development. In 1989, the Society, executives of aerospace companies, the Little Rock School District, and UALR came together to form the Aerospace Education Center Campaign Leadership. The unprecedented public/private partnership has planned an Aerospace Education Center. As the architect's drawing illustrates, the Center combines a museum of aviation history with an Aerospace Technology Magnet High School on a 19.8 acre tract at the Little Rock Regional Airport adjacent to the main terminal, Falcon Jet, and Arkansas Aerospace. The facility will cover 200,000 square feet, including common areas used by both the museum and high school such as the library, cafeteria, and theatre/ auditorium. The upper level of the museum will function as an educational resource for adult programs, and outreach for schools, state and nationwide through a satellite television uplink providea by the Arkansas Electric Cooperatives. The most comprehensive and largest technical and historical aviation and aerospace library collection outside of the Smithsonian's National Air and Space Museum was acquired for the Arkansas Museum of Aviation History. Virtually every civil and military aircraft, rotocraft, and spaceship designed and constructed throughout the world is represented in the collection by technical specifications, photographs, and historical descriptive information. There are well over 5,000 books, 50,000 journals, 200,000 photographs and transparancies, hundreds of rare collectable items signed by famous pilots and aviation personalities, original paintings, scale aircraft models, and unique aircraft parts. The Society has raised over five million dollars in gifts and pledges toward construction of the aviation history museum. The Little Rock School District has budgeted six million dollars for the construction of the Aerospace Technology Magnet High School from funds approved by voters at a property tax election in 1990. The Aerospace Education Center Campaign Leadership believes that Greater Little Rock's future rests on the vitality of its public education system. At all levels of the public education system, educators and industry must develop programs which give students the knowledge and skills that enable them to reach their full economic potential. While the Center will prepare students for aerospace careers, it will also focus the Central Arkansas community on commitment to excellence in education. In March 1819, Arkansas became a territory and the Arkansas Post, the state's first permanent settlement, became its capital. The little French village was soon deemed unsuitable mainly because of its location in the Mississippi Valley, far from the center of the territory. A year later the legislature moved the capital to Little Rock. Today with a metropolitan area spanning a seventy-mile radius, Greater Little Rock MSA is home to over 513,000 people. In the last quarter century, the Greater Little Rock MSA has almost doubled its population - approaching 1,200,000. Today, North Little Rock, the third largest community with a population of 62,000, and Little Rock are joined by the Arkansas River in Pulaski County. Twenty-seven percent of the MSA's population is under 18 years of age. Forty-four percent of the population is within the 18-44 age range. According to the 1990 Census, the population was ------percent Black, -----percent white. B. Little Rock School District The Little Rock School District, encompassing an area in excess of 100 square miles, is the largest school district in the state in terms of enrollment. Enrollment in the schools has increased from 25,975 pupils in 1989 to 26,212 pupils in October 1992. This increase is occuring at the junior high level. 16,538 pupils or 64% of the total district minority enrollment is Black. The percent Black student population exceeds the District 64% average in grades 5-9. The highest percent Black student enrollment is 69% in grade 8. Of the District's forty-nine (49) schools, thiry-six enroll pre-kindergarten or kindergarten through grade 6 students, eight enroll grades 7-9 students, and five enroll grades 10-12 students. Educational program/ school choices include elementary Incentive Schools, grade K-12 Interdistrict Magnet Schools, and elementary area schools. Chart A outlines the number and type of school programs. The text below Chart A defines each type of school and the rationale for selecting certain schools for this project. Chart A - The Organizational Plan for Little Rock Schools n = number of schools ~ie School andlor ucati on Pro IJ'llfll Bern mblry, ~es Pre-IC or -6 JwiorHi~, grades Hgh School~ grades m-1 n n n a.) Area. Md Feeder Schools 22 6 3 b) hcenti-.e Schools 7 NIA NIA c) lntetdistrict ~net Schools 6 2 2 d) h llerdistrict N onm~ net Schools 1 NIA NIA Total 36 8 s a) Area Schools - The elementary school that is the LRSD school for where a student lives is called an Area School. Each Area School feeds into a particular junior high and senior high school. The instructional program focuses on language arts, mathematics, science, and social studies. b) Incentive Schools - Incentive Schools are Pre K-Grade 6 elementary schools located within the immediate downtown area. The percent Black student enrollment for Incentive Schools ranges from 85% to 97%. These schools receive double financial resources to provide a teacher-student ratio of 1:20, additional instructional aides, permanent substitute teachers, and extended day-week-year learning opportunities. An individual learning plan is developed for each student based on the district K-6 core curriculum. Computer-assisted instruction, a student homework hotline, a parenting skills center, and a program for four-year olds are additional features that distinguish incentive from area elementary schools. c) Interdistrict Magnet Schools - As Chart A illustrates, Interdistrict Magnet Schools have been established at all three school levels - elementary, junior high, and senior high. Although operated by the Little Rock School District, students from North Little Rock School District and Pulaski County Special School District (PCSSD) are eligible for enrollment in accord with the desegregation plan. All Interdistrict Magnet Schools are racially balanced within the acceptable range of 55-59 percent black to 41-45 percent white. As Chart A illustrates, there are ten Interdistrict Magnet Schools. These schools provide, in addition to the regular core program, coursework based on a special curricular theme. The desegregation section found on page 8 further describes the purpose and thematic focus for these schools. Chart A indicates there are 31 area and feeder schools. Some of these area/feeder schools are located in racially isolated areas of the school district. This project will establish a new grade 7 -12 inter district magnet 4 of three junior high schools, and the new grade 10 - 12 Aerospace Magnet High School. Each of the three junior high schools exceeds the 64 percent district-wide average for black students. White students will be recruited from across district lines, primarily from North Little Rock and Pulaski County Special School Districts to racially balance the three junior high schools. The new Aerospace Magnet High School will begin magnet program operation for tenth graders the second year of the project. The grade 10 enrollment will consist of 300 grade 9 voluntary student transfers from this magnet's junior high enrollment who will be continuing the magnet curricular career path at the new Aerospace Magnet High School. This project, therefore, will establish the first Pulaski County Interdistrict Magnet continuation program in four secondary level schools consisting of grades 7-9 the first project year and grades 7-10 the second project year. In subsequent non-project years, the Aerospace Technology High School will add grade 11 in 1995-96 and grade 12 in 1996-97 through normal progession of the magnet's grade level enrollment each year. An Aerospace Technology Magnet has been designed in collaboration with the Aerospace Education Center Campaign Leadership, the Universities of Arkansas at Little Rock and Pine Bluff, Henderson State University, and Southern Arkansas University-TECH to attract this magnet's enrollment of 1,200 students. Students who attend each of the three junior high schools will also be eligible to participate in the magnet. The total grade 7 -10 aerospace magnet enrollment will be 2,797 pupils. The breakdown in enrollment is illustrated below: Incoming From outside of LRSD From within LRSD 270 grade 7-9 white students 630 grade 7-9 students 90 grade 10 white students 210 grade 10 students Subtotal: 1,200 Magnet students In-Attendance Enrolled in Magnet Junior High Schools 1597 grade 7-9 students Total: 2,797 students fl By the 1996-97 the Aerospace Magnet High School grade 10-12 enrollment will be at capacity which is 1,800 pupils. The high school enrollment coupled with the grade 7-9 junior high enrollment means the aerospace magnet has the potential to serve 4,597 pupils. The magnet enrollment will reduce black isolation in three junior high schools. C. Interdistrict and Intradistrict Desegregation Measures 1. Background Information on the Court Order The only image that some people have of Little Rock is the one formed in the Fall of 1957 when Governor Orval Faubus defied a federal mandate and tried to use the Arkansas National Guard to keep nine black students from entering Central High School. In Cooper vs. Aaron (1958), the Supreme Court stated that "public opposition to desegregation of the races, no matter how deeply entrenched, could not be allowed to interfere with the full realization of the constitutional rights of black citizens." Twenty-four years later (1982), the Little Rock School District brought suit against North Little Rock and Pulaski County Special School District, claiming that the Constitution compelled the consolidation of the three districts into one governmental unit. This claim was rejected by the courts in 1985 and again in 1986
however, the courts held that interdistrict constitutional violations had occured and must be remedied. Over the course of the next three years, various remedial orders were entered and further appeals were taken to court. Then, in 1988 and 1989, in a sharp departure from the adversary bitterness that had marked this controversy for over thirty years
the parties, including the Joshua intervenors representing the injured class of black schoolchildren and citizens, LRSD, the North Little Rock School District (NLRSD), the Pulaski County Special School District (PCSSD), and the State of Arkansas (Arkansas State Board of Education), agreed to settle the case. They submitted to the District Court four comprehensive agreements covering both interdistrict and intradistrict desegregation measures - agreements referred to by the parties as the "settlement plans." They also submitted a separate but related document, called the "settlement agreement," settling the financial liability of the State of Arkansas. The United States Court of Appeals for the Eighth Circuit reversed this judgement on June 27, 1989, and directed the District Court to adjust the boundary between the LRSD and PCSSD, to revise student attendance within each district to reflect the racial composition of the district, to maintain PCSSD's percent black student enrollment within the range of plus or minus 25% of the districtwide average of blacks by organizational levels
and to limit busing, one-way, to forty-five minutes. 2. The LRSD Desegregation (Settlement) Plan (1989_) The following description is from the record of the United States Court of Appeals for the Eighth Circuit: "Eight of the 31 non-magnet elementary schools will be designated Incentive Schools. Initially they will be all black. These schools will receive compensatory-education programs and two times the level of funding for six years. The plan includes a detailed and volumous description of the kinds of programs that would take place at the Incentive Schools. A salient feature of these schools is a maximum effective student-teacher ratio of twenty to one. Twenty-two of the twenty-three remaining elementary schools will be called Elementary Academies. These schools will have projected student ratios of between 50 and 62 percent black. The other elementary school, Romine, would be an interdistrict school. Any white student can elect to attend an Incentive School, and a black student living in an Incentive School attendance area can opt to attend one of the Elementary Academies." 3. Interdistrict Desegregation Plan The Interdistrict Desegregation Plan is designed to achieve racial balance in the schools and districts of Little Rock, North Little Rock, and Pulaski Country Special School District through voluntary movement primarily to magnet prpgrams. Interdistrict schools are "to obtain a ratio of between 60 percent and 40 percent of either race with the ideal goal of these schools to be 50 percent black/white." The Little Rock School District reports biannually the number and percent of students enrolled by racial background in each of the district's 49 schools. The above data is also sum~arized in terms of the total district (Pre-K-12). Interdistrict magnets are used to attract a specific student population from outside of the district and from within the original district to racially balance the school and district. Participation in a magnet is through student/parent choice. The Magnet Review Committee (MRC), created by the Eight Circuit Court of Appeals in September, 1986, oversees the implementation and operation of the interdistrict magnet schools. Comprised of representatives from each of the three districts, the Committee makes policy on issues such as magnet enrollment, transfers, building capacities, and operating funds. The Magnet Educational Team (MET) is the recruitment arm of the MRC, 7 and is responsible for public information and recruitment strategies and activities. In the Little Rock School District, six elementary schools, three junior high schools, and two high schools have magnet programs (refer to Chart A). Six (6) Interdistrict magnets (4 elementary, 1 junior high, 1 senior high) were created in Little Rock in compliance to the 1985 court opinion. Since 1987, five more interdistrict magnets have been established in the Little Rock School District. Magnets enhance the district's core curriculum. The specially designed curricula is the "hook" for attracting students across district lines. Individual interdistrict magnet school brochures provide a program description. Chart B summarizes the eleven interdistrict magnets in the LRSD by theme and number of schools participating at each school level. Chart B - LRSD Interdistrict Magnet Programs Theme School Level and # of Schools Elementary Junior High High School 1. Early Education* 1 2. Basic Skills 1 3. Basic Skills/Math-Science 2 4. Arts 1 5. Arts and Sciences 1 1 6. International Studies 1 1 1 Subtotal 6 2 2 Total Magnets -10 This is a Pre-K magnet housed in an Incentive School. The majority of LRSD Interdistrict. Magent Programs have been in operation since the 1986-87 school year. Magnet enrollment that year was 3,647 pupils. This year it is 7,250 pupils. The number of pupils enrolled in LRSD individual magnets has increased 50%. The Interdistrict Desegregaton Plan is more than just magnets. The Pulaski County M-to-M (Majority to Minority) Transfer allows a student to transfer from a district and school where his/her race is in the majority to a district and school where his/her race is in the minority. This means that black students in the LRSD may transfer to schools in North Little Rock and the Pulaski County Special School Districts, and white students in NLRSD or Pulaski County SSD may transfer to a Little Rock School District school. The Aerospace Technology Magnet will advance the voluntary desegregation efforts of the Settlement Plans. The district commits that it will "maintain the facilities on a racially integrated basis into perpetuity." (Refer to 2/4/91 Amendment in Appendix.) The Little Rock School District Desegregation Plan, the Pulaski County Special School District Permanent Desegregation Plan, the North Little Rock School District Desegregation Plan, and the Interdistrict Desegregation Plan hold excellent promise for achieving unitary school systems in these three districts. (Exerpted from text of Settlement Plans - refer to Appendix.) 4. The Settlement Agreement The Settlement Agreement provided for payments by the State to the three school districts for desegregation purposes only. Under the agreement, the state makes payment to LRSD, NLRSD, and PCSSD totalling $107,723,175 over the next ten years. The state legislature and the Governor expended these funds without a court order. Moreover, the State also agreed to lend LRSD up to $20,000,000 over the next ten years. The loans are to be forgiven if at any time between the date of the agreement and December 31, 2000 the composite scores of LRSD black students (excluding special education students) on a standardized test agreed upon by the State and LRSD are 90% or greater of the composite scores of LRSD white students (excluding special education students). The settlement plans and the settlement agreement do not limit the District Court's ability to require the creation of additional interdistrict schools. They limit only how new schools may be funded. This funding may include payments by the State for majority-to-minority transfers, but it may not include the imposition on the State of a share of the capital costs of these new facilities. The agreement does not bar the creation of additional interdistrict schools
it simply provides that, when created, they will not be funded in the same way as the six stipulation magnets. (Refer to entire text of Settlement Agreement in Appendix.) The District Court mandated the creation of the Office of Desegregation Monitoring staffed by a Monitor to supervise compliance to the four Settlement Plans and the Settlement Agreement. II. Needs Assessment The Little Rock School District, in conjunction with North Little Rock School District and Pulaski County Special School District, is implementing a court-monitored desegregation plan of which magnet programs and M-to-M transfers are a voluntary option to integrate the three individual school districts. Although Little Rock has achieved racial balance through the creation of interdistrict magnet programs in once racially isolated schools, there are still schools whose percent black to white enrollment exceed the 60%-40% ratio. The district wants to establish more across district voluntary movement of junior high students to bring racially-isolated schools within the balanced range. According to the 1992 LRSD Enrollment Survey, there are three junior high schools that meet this criteria. Three of the junior high schools have been targeted to attract white students primarily from school districts of the Interdistrict (Tri-District) Desegregation Plan, other school districts within close proximity of the Little Rock school districts, and private schools. This plan promotes desegregation. It increases the grade 7-9 white student enrollment at each grade level of three racially (black)-isolated junior high schools. The hook to attain this project's desegregation goals and objectives is the Aerospace Technology curriculum. Since 1900, the United States has become wealthy and powerful by exploiting the rapid changes taking place in technology, world trade, and the international political order. New developments in technology, international competition, demography, and other factors have altered the nation's economic and social landscape. There will be few jobs for those who lack adequate science/technical knowledge and who cannot read, follow directions, or use mathematics. Higher skill requirements of the economy suggest that schools must impove the preparation of the nation's youth in order to economically compete in the global marketplace. This can only be accomplished if the schools have excellence in technology education, communications, problem-solving, and scientific and technological literacy. This district believes it is absolutely necessary to help students understand their technological future if they are to function as responsible, productive members of a competitive society. This district also believes this endeavor must be a cooperative and concentrative effort with this area's prime employers, the aerospace/ aviation industry, the State Department of Education, the Universities of Arkansas, Henderson State University, and Southern Arkansas University-TECH. The aerospace technology education magnet has long range impact for desegregation in the Little Rock School District. First, it involves further voluntary movement of non-district white students to prevent the progressive, increasing isolation of predominantly black junior high schools. Second, this project has carefully planned for a new racially balanced high school to prevent racial isolation in the existing high schools. Between October, 1987 and October, 1992, the Black enrollment increased by 9% from a 51 % Black average to a 60% Black 10 average. The increase will continue due to the progression of the junior high enrollment (69% black average) through the grades. Finally, this district is confident that the aerospace magnet will attract and retain a new enrollment of 360 grade 7-10 white students while maintaining the current enrollment. These are the reasons: 1. "Aerospace Technology" is a statewide public education and economic development effort in accordance with the Arkansas Aerospace Task Force and its creation of the Arkansas Aviation and Aerospace Commission through passage of State Senate Bill 35. Their mission is to provide "the knowledge and skills that will allow students to reach their full economic potential." 2. The Stipulation and Consent Order of February 1991 amended the LRSD Desegregation Plan to include the Aerospace Technology Magnet School(s) and their maintenance as racially integrated facilities. 3. The public and private contributions of funds for up to 6.5 million dollars to construct the aviation history museum which will implement curricular activities during and after magnet school hours in coordination with the magnet's specialized curriculum. 4. A successful millage campaign approved by voters for six million dollars to construct the Aerospace Magnet High School. 5. The Aerospace employment need for a skilled workforce is well known in Arkansas. Specially-trained employees are required to meet new contracts for aircraft and the employment vacancies listed by the Little Rock Airport Commission. Technology education is addressed in conjunction with the study of applied mathematics and physical science. More science and mathematics have been built into the existing curriculum. The academic and technology-integrated curriculum begins in grade seven to better prepare the minority student for future employment, college, and success in finding his/her niche in a technological society. Because of the strong aerospace industry and university linkage, and the hands-on problem solving approach used to learn the curricula, the district foresees the inclusion of some Little Rock elementary schools in the near future. Need 1: The Reduction and Prevention of Minority Group Isolation There is a need to establish a new interdistrict magnet at the junior high level to racially balance three schools. An end-of-project enrollment of 2,797 will enable each of the aerospace magnet schools and total magnet enrollment to reflect a 11 black/ white ratio of between 60 and 40%. The goal reflected by the% black figure in Table 1 is to reduce racial isolation by increasing the number of white pupils in three Little Rock junior high schools. This will bring the junior high school% black student enrollment in line with the Interdistrict Desegregation Plan goal of 50% black/white. TABLE 1 Reduce Now End of Project Receiving Schools % Black % Black 1. Cloverdale JH 73.7 50.0 2. Forest Heights JH 70.4 50.0 3. Southwest JH 75.3 50.0 The goal reflected by the percent black figure in Table 2 is fo prevent black group isolation in the new high school. This will be accomplished through voluntary movement of grade nine pupils from the three aerospace magnet junior high schools. The grade nine enrollment includes M-toM transfers from NLRSD, PCSSD, and other school districts not a part of the Interdistrict Magnet Desegregation Plan
and LRSD pupils provided such movement does not negatively impact the racial balance of the sending junior high schools. This will racially balance the new high school in accordance with the Interdistrict Desegregation Plan. TABLE2 Receiving School New High School Now % Black 70.0* End of Project % Black 50.0 *based on the % black student enrollment average for the desegregated sending junior high schools located in the attendance area of the new high school. 12 Program Goal 1: To reduce or prevent racial isolation in the Little Rock School District Objective 1.a: By September, 1993, the district will reduce racial isolation through recruitment of white students from out-of-district to aerospace magnet programs. The aerospace magnet program will be balanced when the percent black to white figure is within the 60%-40% balanced range or is 50% black/white. Reduce % Minority % Minority Magnet School Before After 1. Cloverdale JH 73.7 50.0 2. Forest Heights JH 70.4 50.0 3. Southwest JH 75.3 50.0 Objective 1.b: By September, 1994 the district will racially balance the new high school through voluntary transfers from the grade 9 continuing magnet enrollment. The new high school will reflect a 50% black/white ratio. Magnet School New High School Prevent % Minority Before 70.0 % Minority After 50.0 Need 2a.1: Strengthening the Knowledge of Academic Content For the past two decades in America, the low level of academic achievement in our secondary school has spelled disaster for our youth and for our economy. The statistics are alarming: a. Ninety-three percent of 17-year olds do not have the capacity to apply mathematical operations in a variety of problem settings. An increasing number of the nation's students are ill-prepared for college courses or jobs that require technical skills. (National Assessment of Educational Progress 1988, p.# 2) b. For generations traditional prejudices have encouraged mathematics achievemmt in only a pcrtioo ct the student pq,ulatia, - middle class white males. Females and minaities with the exceptioo a Agan-Americans were 13 perceived as beth Niess capalie" cf learning mathematics, and needing" it less. (Mathematics Education - Wellspring cf U.S. Industrial Strength, December 1988.) c. In lxxh participation and achievement, American students in science and mathematics are lagging behind previous years and ether countries. (Science and Engineering Indictors, Natienal Science Board, 1990.) d. Only aboot twenty percent ct 10th graders believe that bidogy, chemistry, physics, er gecmetry are needed to qualify fer their first chcice occupatiert Only twenty-eight percent believe they need algebra ( Lengitudinal Survey ct American Yooth, 1988.) e. Schods must imprC1o1e their science instructim to allo.v the nation to base its ecmcrny en high technology. New programs must be developed and strategies reexamined to achieve the sharp focus required. (The Triangle Coolitien fer Science and Techndogy Education, 1988.) Acccrding to the results ct the National Science Foundatien's nationwide study, students are net receiving enoogh hands-a, labcratcry experience. f. The 1.25 grade-level-equivalent decline in the academic achievement cl high schod seniors to.vered the natien's productivity by $86 altien in 19'ir1 and will tower it by more than $200 altien annually by the year 2010 (Journal ct Currio.ilum Studies, 1989). Studies demcnstrate that ccrnpetence in reading, writing, mathematics, science, and proolem solving are strongly related to productivity in alma
t all j~ At the histcric education summit, September 1989, President Bush and the natim's gC1o1emors agreed to six national perlcrmance gools in educatim to be achieved by the year 2000. These two impcrtant goals were among those adq,ted: Goal IV - Science and Mathematics U.S. Students will be first in the wortd in science and mathematics achievement The pocr standing ct U.S. students en intematicnal assessments ct mathematics and sdence achievement is no accident, says a new ASCD task fcrce repcrt. It results frcrn systemic proliems in the quality ct o.irric:ulum and instruction in the United States, the unequal cppcrtunities afferded different students, and peivasive o.iltural beliefs that do little to support high mathematics and science achievement The ASCD t~ fcrce repcrt dtes foor majcr factors a,nttibuting to lo.v U.S. student achievement in mathematics and science. These are: 1) Rdalivdy few :stadmls take uxases that indude high-tevd a..th:id in malhmaalics and sdence Fewer than half c:A students take a chemistry er algrel:ra n course and fewer than ooe in five Erv'er take a rourse in physics, trigonanetry, analysis/precalo.ilus, er calo.ilus. Mcreover, the Aasl'i!'iCll fq 'i!$11'1Y11iw and Cynja,lwn Pevelq,nwtt. Raising Our Sights Jrrp-rovtng u.s. AchieYa'IW!t tn Mathematics and SdenC!f, DlarnlB' 1991, p. 6 14 widespread tracking a students means many pupils - partirularly minaities - are never required to learn high-level content. 2) Wlwaallcs and sdenm rmrimlmn\ as wdl as the ledt-11:s and as!lll!S!IDr"'l!lll!!lldslS tinted tollwm. fail torefted 811: '"flu.tiers d knowledge" about how ddl~ lean best. U.S. mathematics and sdence rurrirulums saa
ftce depth fer coverage, dm't take advantage c:J techndogies ... fail to make camectims amcng the disdplines, and generally ignere the real-life experiences and oognitive develq,ment of students. In general, students assume a passive rde, with teamer talk, textbooks, and worksheets predcrninating. The Natimal C.enter fer Educatim Statistics study recently documented the percmtage a 8th graders whose science teamers ronducted sdentific experiments. Bdh Catholic and private - other religious and ncn-religioos schods - science teachers sutpassed public sdlcds science teachers m frequency -- ance per day, and mce per week - fer prCNiding experimentatim in sdence (Educatim Weelc, September 1992). 3) lr.sbudi..a does Id reflect the need fir all stud1:11ts to llliti1lel c:hailengin& cudeiiL The training and suppcrt afferded teachers too aten fail to retlect the mallenge a delivering high-level cx:ntent Teamer preparatim and inservice suppcrt, dass size and teaming Iced, and teachers' oppcrtunities fer crllal:x:ration and dec:isicn making all hinder the delivery a pdent instruction. 4) Odtur.ai values and dher fa.tms antn"bule to the belief._, fa many sludenls. high addc.:wtid in malh and sienm is not wafh slrMng for ats unallalnalJle. Except fer a small number a highly mctivated students, many pupils appear to be swayed by di~raging rultural attitudes toward math and science prctidency. In additim, the United States is ooe a very feN industrialized demcx:rades that does nct proode strmg incmtives (such as better jcb
) to students who do well in tough high sdlcd math and science coorses. The Natimal Science Board and the ~D Panel urged that all students should be required to take math and science a full four years in grades 9-12. The Natiooal Crundl a Teachers a Mathematics, the Natimal Science Teachers' Assodaticn, and the American Associaticn fer the Advanament a Science also stated that math and science rurrirulums should cx:nnect learning to werk, integrate principles frcrn the two fields and other disciplines, and take better advantage a technologies. Similarly, grooping students by ability and tradcing shoold be eliminated. Natimwide research m tradcing suggests that being placed in a low ability track effectively slams the gate oo any passil:ility that a student can take ro.irses leading to cdlege (Natimal Educatioo Lmgitudinal Study a 1988). 15 Gaal III - Student Adtievement and Otizenship American students will leave grades foor, eight, and twelve having demcnstrated canpetency in challenging subject matter induding English, mathematics_ science, histcry, and geography
and every schcxi in America witl ensure that all students team to use their minds wett so they may be prepared fa responsilie citizenship, further learning, and productive employment in our mcx1em ecmany. In respmse to Goal ni the Secretary ct Labcr's Canmissioo oo Achieving Necessary Skills (SCANS) issued its initial report, What Werk Reqires of Schools. This repcrt identified a three-part foundatioo - oosic skills, thinking skills, and personal q.ialities - that witl be at the heart ct jd:> pertcrmance both fa students gang directly to wak and those planning further educatioo. The SCANS three-part foondatioo and the ASCD panel's science and curriculum recommendations indudtng mere aedit hoors wilt be inarpcrated into the project design. In March 1992, representatives fran the fdlo.ving Arkansas educatioo and industry grrups met to discuss the knowledge and academic ampetendes that students shootd possess to sucx::eed in preparing fer aeraspace/aviatioo careers: Aerospace industry executives Aerospace Educatioo Center Campaign Leardership Aviation Historical Society State Department ct Educaticn Mathematics and Science Consultants, and the Associate Director fer Instructional Programs in Vocational and Technical Education FAA Air Traffic Manager LRSD Superintendent a Schods UALR Schcrl ct Science and Engineering Essentially, the magnet witl strengthen the academic achievement ct magnet work-bamd or cr.itege-1::n.md students in mathematics_ science, techndogy, and ammunicatioo <D'llpetendes in oourses equivalent to cr.itege preparatcry curriculum. Aditions to rurrent typical faeign language oourse ctferings witt indude Russian, Japanese, and German. The planned magnet program ct studies wittt be based oo the Arkansas Plan fer Tech Prep, 2+4+2+2 (February, 1992). Industry represEntatives pointed rut that traditiooat oourses" in general science and mathematics_ gecrnetry, algel:ra, trigooanetry, and English do nct emphasize enoogh practical applicatioos ct a:,ntent, especially these related to the high-tech 9know-how, atility-t<Xio" required in industry. It is imperative that industry and the public schods wcrk together to hlild strong, relevant science/math/ ammunicatioo/techndogy stand into the curriculum. Relevant curriculum 16 TABLE 3 - The Arkansas Minimum Perfcrmance Testing Pr~am - Grade 8 Basic Ski11s A. Mathematics Numeration ldent. whole num. place value Recog. whole num./word name Round whole numbers Recog. dee. word name/std. fm Compare decimals Whole Numbers Add whole numbers Subtract whole numbers Multiply whole numbers Divide whole numbers Solve Reading Problems B. Science Earth History Define Earth History terms Identify evidence which supports theory of plate tectonics Matter and Earth Materlala Identify characteristics of matter, rock types, minerals Identify particles of nucleus/energy levels of atom Define pH Earth Process Define earth processes terms Identify agents of erosion 18 Rational Numbers Change Fraction/equivalent Add/subtract fractions Change Fraction to Decimal Add/subtract decimals Multiply decimals Divide dee. by whole number Write percent as decimal Measurement Select metric/custom meas Determine line seg. length Geometry Identify Shapes Find perimeter ' Probablllty/Statlstlca Inter. charts/tables/graphs Meteorology Define meteorology terms Identify major cloud types, layers of atmosphere/gases used, air pollutants and their sources, four types of precipitation Identify weather instruments Identify lightning causes Interpret data from a temperature graph Oceanography and Watercycle Define Oceanography terms Identify water cycle Identify causes of water pollution Universe/Astronomy Define universe/astronomy terms Energy/Natural Resourc Define environmental terms Identify/classify natural resources as renewable/non-renewable means the ccnnectedness between wcrk and the magnet's specialized cunicula The magnet program must also articulate oourse ccntent and acareer ladder fran LRSD to UALR in Engtneertng Techndogy and LRSD to Henderscn State University in Aviattm. 1. State cl Arkansas Basic Skills Testing The Arkansas Minimum Performance Testing Program is the mandated state effa1 fer repcrting the number and percent of grade 3, 6, and 8 students displaying mastery in reading, mathematics, language arts, scien~ and sod al studies. LRSD minimum perfcrmance testing results fer all students and fer students categcrized by race (Black and White) dOCllment national mathematics and science findings locally, and also ccnfirm the opinion held ty industry on ccntent tested. Tal:ie 3, frund m the cppa
ite page, displays what basic skills are tested in mathematics and science An analysis a what is tested and how is indicated in the ccnduding statements below Table 3. This informattm is pcrtrayed to show the need fer a rigcroos mathematics and science linked program 17 Test items fer science and mathematics reflect kna.vledge and slcills typic.al of an upper elementary grade program Measurement and gecmetry is minimal. Testing ct physic.al science CX11cepts is limited. Test items indicated by' the werds recognize, identify, determine, select, define, ask students to recall infonnattcn, the la.vest level ct thinking per Ilcx:m's Taxcnomy. Conduding Needs Statements It interdistrict and district magnet students are, by the year 2000, to leavt. grade 8 having demcnstrated ccmpetency in challenging suqect matter, then this interdistrict magnet must provide the fdlowtng: The applicaticn ct mathematic.al skills in science thrrugh a hands-en industry-relevant program which measures student ruta:mes thrrugh perfcrmance-based assessment. Academic antent strengthened by' ccnnecting ooncepts fa earth, life, and physical sciences to engineering tedmdogy and aviattcn, and teaching fer a:nceptual understanding. An instructiooal approach with 100% utilizaticn ct the science process slct11s and experimental design. The use ct technology as an instructicnal tod in anjuncticn with ccmputer simulatioos and applicatioos fer rearding and interpreting data. TaHe 4 repats the percentage ct grade 8 students (ct the Aerospace Magnet junicr high schools) passing the Arkansas Minimum Perfamance Testing Program by race and gender catagaies as ccmpared to the percent ~ng fer all students in the district. TABLE 4 - The Arkansas Minimum Perfamance Testing Program - Grade 8 Academic Area Junior Hlah SchooUDlatrfct Percent Passlna All Students White Students BlackStudents SCIENCE Male Female Male Female District Coverdale JH 64 95 79 70 48 Forest Heights JH 62 83 96 49 53 Southwest JH 46 n 33 46 35 MA THEMATICS District Cloverdale JH 86 95 89 83 85 Forest Heights JH 80 87 93 70 81 Southwest JH 75 87 76 69 73 19 Results dearly sho.v there is a disparity in mathematics and sdence perfcrmance between white and 1:iack students. Major differences in the percent passing rate occur between 1:iack and white males in ooth sut
ect area5i and white and 1:iack females in sdenc:e. The wide race-gender perfcrmance gap substantiates the need to strengthen how sdence is taught to ensure equal aa:ess to.vard progress in the cxre curriculum 2. Stanford Achievement Test. Eighth Editim Students in the Little Rock School Ilstrict also take the Stanford Achievement Test each Spring. Stanford assesses achievement in all cxntent areas - Reading, :Mathematics, Language, Listening, Science, and Social Science. The Science Sllrtest reflects the natimal trend in science curriculum to.vard emphasizing a:ncepts ct science rather than isolated facts. HONever, Stanford uses the traditimal divisims - physical science, 1:idogical sdenc:e, and earth/space science as the vehicles fa testing skills and understanding ct basic oona?pts. The prqxrtims in which the area.5 a science are represented m the Sllrtest retied the emphasis each receives natimally. In mathematics, Stanford has three Sllqec:ts: Cmrepts a Number, :Mathematics Computaticn, and :Mathematics Applicatims. Special soores in using Jnfamation and Thinking Skills are derived fran an evaluatim ct responses students make to items embedded in several Sllrtests such as Mathemati~ Applicatims, Science, Scx:ial Science, Language, and Reading Canprehension. Grade eight and nine beio.v nam percentile scxres fa students enrdled in the three magnet junior high schods are sho.vn on the next page in Tatie 5 fa :Mathematics, Science, Using Jnformaticn, and Thinking Skills. Results are expressed as the percent ct students in q.iartiles me and two who scxred at a beiON a specified percentile scxre. Taal district percentile scxres are used as a basis fa cx:mparism to individual schod results. 20 G R A D E 8 9 8 9 8 9 8 9 Content Area by Quartiles DISTRICT N = 1669 N = 1625 SCHOOLS Cloverdale JH N =214 N = 199 Forest Heights JH N=205 N =210 Southweat JH N = 167 N = 183 TABLE 5 - Stanferd Achievement Test Spring 1992 Grades 8 and 9 Percentile Sa:res Mathematica Science Us~n Info. Pcentffe ecore Pcer1tlle ecore P ecore 01 02 01 02 01 02 - I 17 35 23 40 22 41 13 29 27 45 28 46 15 28 21 36 17 35 13 23 27 39 26 43 15 31 21 40 20 38 18 30 30 50 31 51 13 23 21 36 20 35 9 21 24 36 26 43 Quartile 2 - 50% cl students sccred at er beiow these sares Quartile 1 - 25~ cl students sccred at er beiow these sares Thlnklnff Skills Pcer111 ecore 01 02 20 40 23 41 17 34 21 55 15 35 22 43 17 28 20 36 Results indicate, e,ccept in a,e instan~ that prcposed magnet schods have sares lower than the district. In oontrast to the Arkansas Minimum Protidency Testing, students faired better in sdence than in mathematics. Spring 1992 was the first time the LRSD has given the Stanferd Achievement Test The percentile sares shown in Table 5 will serve as baseline data fer devEicping this magnet's student performance oojectives in the academics. Need 2a2: The Underrep-esentation cl Mincrities in Science and Math The Congres.5iaially estaliished Task Ferce a, Wanen, Mincrities, and the Handicapped in Science and Technology report, 0tanging Amaica: The New Face ct Science and Engineering, fwnd that Blacks, who romprise 12% ct the U.S. pqrulation, make up just 2~ ct all sdentists and engineers. The findings are especially 21 unsettling considering changing demographics. Prqectia,s indicate that by the year 2000, Blacks and Hispanics a:rnl:ined will make up 47% a the American students enrdlment. As a result it is imperative that the naticn and local school districts take extraordinary steps to prepare minorities fa- greater levels a partidpatia, in science, math, and engineering. The Quality F.ducatia, fa- Mina-ities Plan fa- improving sdence and mathematics instructia, nationally calls for q.iadrupling the number c:i mina'ity students receiving bachela-'s degrees in the sciences and engineering from 17,000 in 1987 tt, 68,000 ~ 2000 (F.ducatia, Week, April 1992). In the Little Rock Sd\cxi Ilstrict 68% c:i the grade 7-9 enrollment is Black. This is a 7% inaease over 1987 figures. LRSD anticipates a:ntinued gains in the number/ percent a Black students. The aitical issue c:i underrepresented minorities, i.e. B1acks, and the need to 1:ring Blacks up to parity in perfa-mance and graduaticn rates, and in cdlege enrdlment is a goa1 a the LRSD as evidenced in the Pulaski County School Desegregation Case Settlement Plans and Agreement: If any a the Incentive Schcrls remains rada11y identifialie (80% or ma-e Blade) after six years, LRSD has explicitly a:mmitted itself to cn1tinue pr~ viding a:rnpensata-y and enhancement funding (refer to page 4). 1t at any time between the date c:i this agreement and December 31, 2000, the a:rnfX]Site sares a LRSD Blade students (exduding special educatim students) a, a standardized test are 90% a- greater a the cxmpa
ite scores a LRSD white students (exduding special educatia, students), the esaONed funds will be paid to LRSD and any wtstanding loans wi11 be fa-given. The intent is that LRSD wi11 receive 20 millicn ddlars plus any accrued interest if its goa1 c:i in~ing student achievement is reached and that the State will be repaid in fu11 amwnt a all loans plus interest if the LRSD does nd reach its goal (September 1989). The magnet enrolls 1,571 Blade students. Curria.tlum focuses a, math/science cn1tent as related to careers in the Aera
pace industry. Additimally, the magnet provides the student with nine (9) career cpticns artiallated to university programs. This magnet was purposefully designed to lay the fwndation fa- later academic perfamance and interest in math and science related fields. Induded in the design is career cnmseUng. Career camseling will stress in the student selfworth, motivaticn, and a:rnmitment to accxmplish personal goals in learning and in Aera
pace career preparatirn. The sdlcxi district, industry, and higher educatim believe this ailaborative etfm to develcp a high tech, marketalie skills magnet wi11 a:nttibute significantly to raising Black student acheivement in mathematics and science, and to increasing the number a blade students receiving associate and 1:adlelor degrees in engineering tedmdogy and airway science. 22 Need 2h ~etc.ping Marketarie Technical Skills America's on~axnmanding lead in the aitical techndogtes driving ea:nanic growth and natialal security is selwsly threatened by faeign ampetitas, the Coondl al Competitiveness said in its repcrt Gaining New Grwnd: Technd~ Ptiatties fa America's Future. The term High-Tech is used to describe a wide variety c:i rosinesses and industry which indude: aercspace, a:mputers and software, telecx:1rn11unications, electralic compments, medical technology, instruments fa measuring and cxntrolling manufacturing proces.5es, energy, environmental, phctographic, lasers and cptical, and data processing services. The Natialal Center fa Advanced Techndogies (NCAn a the Aerospace Industries Asscx:iatial (AIA) Key Techndogies fa the Year 2000 Program have indentifted these high-priaity techndogies: Ccrnputatialal Science Satware ~elcpment Advanced Metallic Structures Advanced Composites Superconductivity tntra-Reliarie Electralic Systems Artificial lntellegence Airtreathing Prcpulsial Rodcet Prcpulsion Optical Information Processing Advanced Senscrs These techndogies represent a shared view a U.S. technology requirements. Gitical technologies in Engineering Prcxiudial and. Electronic Canponents where the United States is falling behind a will net have a presence are represented in Tatie 6 al the next page. U.S. Departmens of Comnerce anl W'ense
W.te House Clflce of SdCIICe and Ta::hnology (Refer to Appendix for defintions anl list of CX>nlributing orgarizali0111. 23 TABLE 6: Tedmd~es in Which the United States is Weak, Losing Badly, er HAS LOST Engineering and Pnxbilc:n Tedmdqpes Design for Manufacturing Design a Manufacturing Processes Aexilie Manufacturing High-Speed Machining Predsim Machining and Perming lntegratim c:J Research, Design, and Manufacturing Integrated Orwit Fabricatim and Test Equipment Rolx)tiQ
and Autanated Equipment Tctal Quality Management Eediud~ G.up.ai.erds Memory Cllips Printed Orcuit Board Techndogy Optical lnfcrmatim Sterage Multichip Packaging Systems Liquid Crystal Displays Electro StatiQ
Swrce: Ca.mdl m Canpetitiveness
partial listing This infcrmation has implicatims fer the need a this magnet to - teach industrial relevant technology skills in state-of-the-art technology laooratories - place a heavy fcx:us m the application c:J scientific knowledge - use engineers and technicians fran industry as instructors - provide industry-msed learning experiences for students. Students in this magnet are primarily being trained as technicians. Technicians working with autcmated equipment must be familiar with lxth software and hardware used by a:,mputers and miaoprcx:es&rs. The development, design, installatim, calil:ratioo, manufacture, assembly, and fabrication processes using sophisticated equipment, tools, machines, and canputers require a roml:ination a knowledge and skills extending far beymd the simple fail-safe mechanical devices c:J a few decades ago The aera
pace industry and its array c:J suppliers and sub-cxntracters are among those that will increasingly require techndogically literate entry level werkers. The American Vocatimal As&x:iation (AV A) and the Center fer Oc:cupatimal 24 Research and I:evelcpment (CORD) pcint wt that technicians currently being prepared for entry in tana-row's werk ferc:e shwld possess several important characteristics. A fei.v ci these are highlighted belo.v because they have ramificatiais on the curriculum desaibed later. 1. , 3. 4. A BROAD KNOWLEDGE BASE: They must possess fundamental academic skills in reading, cxrnmunicating, computing, and applied science. COMPUTER LITERACY: Many high tech processes are cxrnputerized. Thus workers shwld pa
~ a basic understanding ci a::mputers and their applicaticrts in manufacturing and management infamatia, systems. At base, students should have the kno.vledge necessary to ~ and use miaopr~s er intelligent computer terminals using cxrnmerdally available scitware packages. AWARENFSS OF A RAPIDLY CHANGING WORK ENVIRONMENT: Develq:,ments in CAD (cxrnputer aided design) and CAM (computer aided manufacturing) alaig with advances in telea::rnmunicatiais, integrated circuits_ laser/c:ptics and ether computer applicatims assure that techndogy will continue to grow and expand. Thus, technical werkers require a broad base in technical and mathematical kno.vledge so that they can learn nei.v techndogies and assimilate nei.v infa-matia, after they are employed. UNDERSTANDING OF A SYSfEMS ORIENTATION: Modern manufacturing techniques are cxrnprised ci a:mplex inter-related systems of electrical, electraiic, pneumatic, hydraulic, thermal, and q:>tical devices. People who werk with such equipment need a broad understanding ci such systems. Specialists in each ci these fields will still be required, but a grasp ci the overall systems ci produdia, will be impcrtanl This grasp calls fer an interdisciplinary approach to training. 'With the diversity a high technologies, the need fer new <XJJrses is great. This will require LRSD to integrate techndogies and new content into easting <XJJrses as well as aeate specialized <XJJrses a study. Some examples in this magnet are Computer-aided Design (CAD) Applications_ Lego Logo Rdxxics_ High Tech Presentatiais, Aitway Science Olrriculutl\ and Quantitative Literacy fer ~ Althwgh LRSD has prepared <XJJrse desaiptions and wtlines (ref er to appendix), additicrtal a:Jltent outlining labcratcry and design prqects need to be develq:>ed with aera.pace/aviatia, representatives and the university. Hight and space cmcepts need to be infused into the new science curriculum thus aeating the aerospace science <XJJrse a study. In additia,, <XJJrse content needs to be incaporated into an assessment design that measures actual student performance in academic and werk-based learning requirements. 25 Need 2c Empl~t and Training Needs in the Aera
pace Industry Tcxiay in our country there is a aitical need for highly-skilled state-a-the-art technicians in the aeraspace industry. Aaxrding to testimeny by the Arlcansas Aerospace Task Face, Tue greatest chattenge is to aeate an educated workface able to rapidly meet the needs a the industry. Although there witt always be a need fa spedalized training, in the Ieng term mudl can be dene to better prepare students fa emplOjtnerlt Education is our largest investment in Arkansas and that investment prq,erty focused can be our ma
t significant advantage CNer ether states. This statement parallels the disturting finding a the U.S. Labor IRpartment's Secretary's Canmission en Achieving N~ Skills (SCANS): Mae than half a all young peq,le leave schoo without the skills needed fa prcxiuctive empl~t. These young pEq)le witt face the tieak prospect a dead-end jdJ after dead-end jdJ interrupted only by periods a unemployment" (Education Week, May t 992). Aax:rding to the Natienal Center en Educatien and the E<Dtany, the average skill level a graduates net lnmd fa cxilege is the functienal ecp.livalent a about a 7th a 8th grade achievement level. ~ at risk are students in the so-called general and vocational "tracks. Because employers generally aren't interested in the oourses jdJ applicants have taken a the grades they have earned, these students have little inCEntive to take tough academic dasses a to earn high marks. As a result, high schod becanes a hdding tank fa tha
e not gcing en to cxilege. Researdlers studying the wcrkface pcint to an aninous sign: gcx:x:i jct>s - the kind that ctfer reasonatie pay and the cppcrtunity to advance aleng a career ladder - are gradually being shut ctf to students fresh out a school. The ma
t prominant explanation fa such findings is that while the skill and knowledge requirements fa entry and advancement in the wakf ace are rising, graduates are nd: being prepared to meet inaeased demands. New wakers must be aeative and respa-lsible proolem solvers and have the skills and attitudes on whidl employers can b.lild, acxxrding to the SCANS Canmissicn "Traditienal jct>s are changing and new job, are created everyday. High paying, b.lt unskilled jct>s are disappearing. What the Commissien calls '"high-perfamance" wakplaces are mae flexitie and rustaner aiented. Schcds must teadl the skills pocple need to be productive and adaptable wa-kers. A commitment to meet this challenge was adopted in a resolutia, by the Board ct Directa-s a the Oty a Little Rc:x:k to use ea:nanic develcpment funds to develq:> an Aerospace Museum and f:ducatien Center. Resduticns pertinent to the empl~t and training need fa this magnet are stated below: '"Whe:eas. the dfy' d litlle Rak bas mailllained an eamanlc ceMqxueul fund so that the city Cilll enwmage .illld pUide lhe llliilllnlal3II d j~ and 26 'Whel zm dties and stales thmaghoat rm-naUcn cudinue lo me funds fa- eacn::ullc develcp:te4 to ptDde the amllon and ~ d ~ and \\k:ca. the d9 llwgh tis lmillDi~ Dewlqm.ad lbnd made availalJle S3 miOicn to fadlffale the aealim d mere than 3111 jdJs al Alkansash-iiifMI
...t va...ca. dtiZl!IIS and bushrm have janm lcgellNS toplan fa ... ... ., .. e UliiSi:illll and the lit8e Rim Jtwg. iifMP "fedmdogy Mag11et Sd1DCl (aflnfl'Ulty ti-. >en ,a e Cenlaj as part d the litOe Rim Abpn arm cnrp~ and \WK.ca. the di wiD beudit .ind be slrmglhened by .. Jw-1 -,ae r..m11rtoaliitie rm- dtizms to be tralrel fajdJs in therelaled a,1-,:ae hdistrywhic:h is gt<Mingin little Ra:k.. Two SCANS repats outline the slcills students should be taught and what needs to be done to Effectively teach them. In additirn to the fourydatirn skills (refer to page 5), there is a set a five cx:mpetendes that are at the oore a jci:> pertcrmance. Acarding to SCANS these will be needed a all graduates, 1:xlth the cdlege-ba.md and those directly entering the wakfcrce. The five wakplace rompetendes are desaibed below: Resam:es Fmployees need to be able to identify, organize, plan, and allocate resources (such as time, mrney, materials and facilities, and human resources). hdapa50iwl stills. Employees should be able to wak effectively with ethers. F.xamples are theabilities to participate as a member a a team, teach ethers new slcills, serve dients or custaners, exercise leadership. negotiate, and wak with diverse people lnfmmallm. Employees need to be able to acquir~ evaluate, interpret, and ccmmunicate informatirn, as well as to use amputers to process infcrmatia,. Sy:stma. Employees must understand how social, aganizational, and techndogical systems wak and cperate effectively within them They must tllCllita and arred perfcrmance, improve the quality a prcx:1ucts and services in existing systems and develq> new a alternative systEms. Tedwdcgy. Employees must be al:ie to judge which sets of prcx:edu~ tools, a machines, induding amputers and their programs, will prcx:1uce the desired results. They must be al:ie to set up and q,a-ate amputers and their programming systems as well as maintain and troubleshoot techndogy. 27 The Canmissirn's plan as detailed in America's Choice High Skills or Low Wages also reccmmends that: All students must meet a nalicnal slandard d educaticnal eca.tlena: by age 16 or SCDt themaftel'. Students passing a series d perfmnanm-based zu:
:a:uls that reffed: the standard waild reaive a Certificale d Initial Maslesy. Nier t&Eiving the amfi~ sludmts waild diuaie to go to wak_ enter a ailegep1t, pttan, a study fa a tedmical or pde!liiicnal amfiClle. In this magnet's prqect design, the SCANS ccmpetencies will be inrotpcrated into the mathematics, science and technical crurses of study as well as the design for measuring student performance and the attainment d this magnet's program oqectives. The change this magnet envisions will require additirnal resoorces through the funding of this prgect. Amrng the most impcrtant will be investments in curriculum writing, teacrer training, technology and instructional material including oomputer-based and multimedia material. To address the employment and technical training needs, Little Rock's Aera
pace Campaign Leadership and Industry has turned to LRSD, UALR, and Hendersoo State University to develcp a better student. With the assistance of the United States Department of Educatirn and the Little Rod< Aera
pace Campaign Leadership and industries, LRSD beleives it can provide a state-a-the-art technology-driven Mathematics, Airway Science and Engineering Magnet Program which meets the purpa
es, priaities, and special ccnsideratirns d the MSAP as well as addresses the natirnal imperative to maintain a wcrldwide canpetitive lead in techndogy. Progaan Goai 2 To strengthen the kno.vledge a Academic Crntent and to develcp marketable technical skills a students in project magnet schools. Oqective 2.a 1: Performance Assessment: Applied Science/Mathematics/Techndogy Integraticn with SCANS Wcrkplace Competencies and the Occupatioo Program Majors By the condusicn a the prqect period at least 80% of the grade 7-10 students enrolled in the magnet schoo program will have attained the Wcrk-Rea'f,Y Proficiency Levela en the LRSD-SCANS Perfamance-Based Assessment administered the first week d May. a What Wcrk Requires d School, a SCANS Report for America 2000, p. 24-29 (U.S. Department d Labor Secretary's Ccmmission rn A~ieving Necessary Skills. 28 b Perfamance Standards will be set the first prgect year when actual baseline data beccmes available. O1:-
ective 2.a2: Performance Assessment: Certificates ci Initial Mastery (CIM) By the a::nlusion of the prgect period in 1995, at least 90% ci the grade 10 students in the magnet program will have achieved a Certificate ci Initial Masterya as repaied on the student's Cumulative Resume and verified by the site magnet Assistant Principal. ac1M is defined as the attainment ci an overall standard. The overall standard will be estatiished by the end ci the first prgect year in relatirn to student ootcx:rnes repaied for d.Jjectives 2.a 1 and 2.b, and the Cumulative Resume. The Cumulative Resume will show prcticiency levels fcr the wcrkplace cx:rnpetencies and Aerospace Techndogy courses completed based on evaluatirn results reflected in Pcrtfdias and Perfa-man~Based Assessment materials. Leaming a Living: A Blueprint fcr High Perfcrmance. A SCANS Repcrt fcr America 2000, pages 60-68. Objective 2.b: Pcrtfdio Assessment By the ca,dusirn ci the project period, 80% ci the grade 7-12 students enrdled in the magnet schcxi program will scx:re at cr aoove an established competene,ya sare oo each ci foor ( 4) teacher and student selected SCANS Integrated Assignments. One repai cr assignment must be selected fran each of the four (4) major areas. The extent to which this d.Jjective is met will be determined by teacher records and verified by the site magnet Assistant Principal. aeanpetency will be defined as an average ci at least 2 on each report using the follCJNing scale: 4 Well beyond expec:tatirns fcr grade level
extracrdinary. 3 Does better than expectatirns fcr grade level
cx:rnpetent/fluent. 2 At level cr average performance fcr grade level
appears cx:rnfaiable with demands ci prgec:t. 1 Approaching average pertcrmance for this grade level
some skill/ comprehensirn acquired. 0 Novice
no evidence of relevant skill/ cx:rnprehension Computer Technology 1. Word Processing/ Keyboarding - Using proper keyboarding and editing skills to produce documents. 2. Graphic Design: Using the graphic program to produce graphics. 3. Communicatirns: Using speaking, writing, video cr hypermedia to 29 express an idea. 4. Programming: Being able to write a set d instruc:t:ioos in the hypermedia or LEGO/ LOGO environments. and Technology Lab 2000 1. 2. 3. 4. and Aeros_pace Science 1. Scientific Method - Experimental Design: Given a questicn er a prol::iem, students will fcrmulate a hypcthesis, design an experiment, observe and draw ca,dusions fran the data 2. Process Skills: Canparing, erganizing, categcrizing, relating, infening, applying. 3. Computer Technology fer Scientific Purpcses: Having a product that reflects the use ct computers, laser discs, VCR's, cala.tlators, and science equipment. 4. Self-Assessment/Self-Esteem: Student and teacher selected werk will be placed in individual student pcrtfdias. and Airway Science 1. 2. 3. 4. or Engineering Technology 1. 30 I 2. 3. 4. olective 2.d Program Effectiveness During June ci each prqect year, at least 80% ci the parents, students, and teachers will rate the fdlowing items "effective" oo a locally develc:ped survey: breadth ci curriClllum program qua! ity parent training teacher training use of community resources program ccntributions to career c:ptions improved student achievement pcsitive ccntributioo to student career plans By the conclusion of the project in 1995, the percent of Aerospace School students scoring in the second, third and fourth quartiles on the Stanford Achievement Test : in mathematics and science will exceed the percent of students scoring in the sec~nd, third and fourth quartile~. in other LRSD schools_ in grades 8, 9 and 10. 31 I : Quality of Project Design The project includes the f dlowing topics: A OJerview: The Aera
pace Techndogy Curriwlum 1. Applied Science and Science Labcratay 2. Applied Mathematics 3. Computer Technology and the Canputer Tedmdogy Laboratay 4. Faeign Languages 5. Engineering Techndogy 6. Aviation 7. SCANS I<now-Ho.v 8. Work-Based and Wak-Site Leaming and Experience B. Aerospace Technology in Grades Seven and Eight (Junior High Level) 1. Content Knowledge in Mathematics 2. Content Knowledge in Sdence 3. Content I<no.vledge in Canputer Techndogy 4. The Techndogy Lab 2000 Cuniwlum Integrattoo c.enter 5. Infamatioo and Guidance C Aerospace Technology in Grades Nine and Ten 1. Content I<no.vledge in Mathematics, Sden~ and Computer Technology 2. Content l<nONledge in Engineering Techndogy 3. The Techndogy Lab 2000: Scientific Uterac.y Center 4. Caltent Knowledge in Airway Science 5. Workplace Readiness and Industry/ Business Internships 0 . Instruc:ticnal Approaches and ft&essment a Student Perfamance 1. Learning in Caltm 2. Product Development Team.1/Cooperative Leaming 3. The Patfdio 4. Perfanance-Based Assessment E. Teacher and Student Organizatioo F. flexible Scheduling G. The Aviatiat Museum Educaticn Department Docent Program 1. Courses a Instruc:tioo 2. The Library 3. School Visitatiat Program 4. Planetarium 5. Imax Theater ! l The Aerospace Technology Curriculum ---------.... Applied Mathematica Aerospaoe Mathematics (7) Applied Mathematics I (8) Applied Mathematics II (9) Oescnptive Geometry (10 Technical Algebra II (11) Ouant,tallve Literacy lot Aerospace (12) Technical Algebra I (8) Descriptive Geometry (9) Tecmical Algebra II (10) Advanced Algebra/ Trigonometry ( 11) Calcuus (12) Aviation Airway Science Intro AeronauticsA.ab (9) or General Aviation (9) or Machine Shop Technology (9) Programming Language (10) or Aircraft Systems Theory (10) or Powerplant Theory & Maintenance (10) Powerplant Theory (11) Of Electncal Circuit Analysis ( 11) Fortran..Cobol ( 11) or Av1at1on SaletyA..egislation/Air Transportation (11) Pnvate Pilot Cert.A.ab (12) Powerplant Systems (12) or Air Traffic Control" (12) or Assembler Language & Operating Systems Internship I, II (11 , 12) Aerodynamics & Performance (12) Classes w,11 be instructed ,n Museum of Aviation HistOfy - Comput Technology Integrated Software Applications and Logowriter Robotics (7) Hypercard.tiypermedia and Aerospaoe Pr9-CAO(8) HI-Tech Preeentationl (9, 10) Applied Comnulicallon (English) (12) I Foreign Language Japaneee or RuNian or~ or Spanish or German Magnet Course Sequences Grad 7-12 Title Ill Magnet Schools Asaistance, Sec. 3003: Statement of PurJ)098 (2) - Courses of instruction to substantialy strengthen academe subjects and the tangible/ marketable vocational skills. --- Applied Science Aeroepaoe Science I (7) Aeroapece Science II (8) Aeroepace Biology (9) ~ Phyaical Science (10) I Chemistry (10) Aerodynamcs and Meteorology (11) Physics ( 11) Deea1)tive Mtro11omy & Physical Geology (12) Engineering Technology Intro. Concurent Ens
neering (9) or km>. eon,,ue. Sc:lence (9) Coquer-Alded O.V, Appbtons (10) or Marulldwing E11gl11wtng Technology I, II (10, 11) E1ec:nl lice Engineer' ig TectuologyCAD I. II (10, 11) AdvMOed Con1)Ullr-Aided Design Applications (11) Progran'ln'ing tor Englneer:.ig Majors (12) Fabrication DNis,l Prqecta (12) or Mechanical Systems DP (12) or Manufacturing Design Project (12) Internship I, II (11, 12) - - H. The Staff Training Plan L The Aviation Museum Educaticnal Reswrce Center fer Teachers J. The Planning Canpcnent to Develc:p Aera
pace Tochndogy Magnet Curriculum fer the High Schoo K Bringing Students Fran Different Backgroonds Together L Staff Experience in and Knowledge d Curriculum Development and Desegregation Strategies M Addressing Educaticnal Needs Appropriate to Students Enrdled N. Parental Decisicn-Making and Involvement Each tc:pic is desaibed in detail after the averview to this secticn. A Overview What fdlows is a oomprehensive summary cl the Aera
pace Technology c:urridum As shown in the erganizaticnal chart below, the Aerospace Techndogy Magnet is erganized into two cxx:upatiooal program majers d nine career tracks and an interrelated academic and tedlndogy cxre of requirements ansisting of Applied Mathematics and Science, and Canputer Techndogy. The Aerospace Technology Curriculum Elective Elective Integration Core Integration Aviation Applied Engineering Airway Science Science Technology Aitway Coml)IUf Manufadl.ling Engineering Sa.nee Applied Technology A:lrway Science Mathematica Management * * Electronics Engineering Alo-craft Systems Computer Technology Management Technology Computer Engineering Aviation Maintenance Tedinology Professional Pilot Foreign Language Mechanical Engineering Tedinology A structured sequence ci courses has been specifically designed fcr each ci the three curricular canponents to enhance participants' prospects fcr immediate employment cr continued education following high school graduation. All magnet students in grades seven through ten will participate in applied mathematics and science, and a:mputer technology roursework each year. This means that magnet students will take one mere year d math and two more years of science than is required for high schoo graduation. All magnet students have the optirn of beginning f ereign language instructia, in grade 7, 8, er 9 in a,e language d their chcice. This allCMts for six years of c:x:ncentrated study d a global language. Magnet students will select ether the Aviatia, er Engineering Techndogy Occupational Magnet program majer and a career track within the selected occupatia,al area upa, entering grade nine. The magnet student will then fdlCMt the specialized course sequence throogh grade 12, thereby rompleting the program in his/her occupational program majer. The chart a, the cpposite page ootlines the curriculum by' a::rnprnents and grade levels fer the entire grade 7-12 aera
pace magnet. Grade 7-10 course sequences willl be implemented during the two year MSAP prqect period (1993-95). Grade 10 students will ccntinue the curricular path as eleventh graders in 1995-96 and as twelfth graders in 1996-97. The latter two years (1995-97) are not MSAP prqect years fer this particular application, theref er~ courses intrcx:iuced during these two years will be desaibed in the Canmitment and Capacity sectia, of this application. The magnet's articulated course sequences in Mathematics and Science, Aviation, and Engineering Techndogy are designed fer students to romplete in advance some requirements to.vard receipt a Federal Aviatirn Administration (FAA) certificates, and/ a Associate d Applied Science or Bachelcr a Science degrees. 1. Applied Science and Sdence Lal:xratg:y Aerospace Science ccntent will be presented in ccnnectia, with its applicatirns in aviatioo/space, design and production technology, and envirrnment protection. This will be aa::omplished throogh the reaganization a the district's science curriculum and the aera
pace science applications (refer to Appendix) to themes. Themes are ideas that integrate the ccncepts of different scientific disciplines. Crnnecting the impatant science ccncepts between existing curriculum and aerospace science with science themes will improve students' ability to make more meaningful the relatirnships between science c:x:nc:epts and ether related disciplines. Amrng the maja themes that will be used are tha
e discussed in Science Fer All Americans: * Chapter 11, Common Themes, p. 155. See Appendix. Systems Coostancy Patterns c:i O,ange Scale Model Evolution Table 1 represents a pattern fer a a:ntent matrix that will be filled in with a:ncepts and thematic ideas. Table 1 - A Pattern for a Content Matrix Grade 7 8 9 10 Phyalcal Science General Science Earth Science Aerospace Science LHe Aviatlorv Product erw, a 11 a El Science Spece Engln..,ing .... Unifying Concepts Theme(a) Subconcepts The magnet's science teacher specialists wi11 use the pattern fer a a:ntent matrix to design the sa:pe and sequence d the Aerospace Science curriculum (grades 7-8) Aerospace lidogy (grade 9) Aerospace Physical Science (grade 10) in cxnjunctia, with the district's General Science and lidogy airticulum. Building the matrix will require that magnet teacher specialists have a cxncentrated pericxi d time free from teaching respcnsibilities. This applicatim asks for cuniculum writing time during the summers and after school hrurs to develop the matrix in collabcratim with the universities and industry. Implementatim of the matrix will be enhanced by student investigatim and experimentatia, in a laboratory setting. This program also requires a science labcratcry at each magnet site for students to experience hands-a, activities keyed to the matrix. The lal::x:lratcry will be set-up to indude scientific equipment and materials, fifteen canputers and canputer interface boxes, probeware, and software pad<ages that will allow students to simulate experiences and use canputer utilities (spreadsheet, graphing programs, database, wcrd processing). The district is asking fer magnet program assistance to enable its 1:fack students and incaning white students to participate together in these specialty-designed experiences. The lab will be staffed by a prqect-hired science teacher specialist who will be a member ci a,e of the magnet's Science/Math/TECH instructirnal teams. This instructia,al team will direct each ci its four teams of 30 magnet students in the labcratcry per the flexible schedule desaibed a, page __ . To determine impcrtant aspects of lal:xratory implementatia, major goals have been established. These are student attainment ci: Manipulative and canmunicative skills to indude the manipulation of materials and equipment, and the cdlectioo/ organizatioo/ canmunication ci information fran lalx:ratcry experiments and activities Ratiooal and aeative thinking precesses throogh obsetving and ccnducting statistical procedures, through cdlecting, dassifying, and measuring oqects
throogh indentifying and ccntrdling variables in ccntrolled experiments This goal invdves students in learning the scientific precesses ci cbserving, canmuni~ting, canparing, crganizing, relating, and applying. The district envisioos the fdlowing scenario as to ooe way magnet students witl learn in the special science laboratory: The Aerospace science teacher specialist prOv'ides an interactive video disc presentation desaihng gravity as fcrce. Because it is hooked to a canputer program, the infcrmatioo on the disk will be accessed in a variety ci ways (e.g., noo-linear). Throughoot the viewing ci the video, students will disa.iss gravity and fcrmulate answers to fellow students' questions about gravity a, ether planets in oor sdar system. To protide them with additiooal infcrmatioo, the students will have acx:ess to 1) the Aerospace Educatioo Center films, 2) university programs, and 3) a variety d other infcrmaticn sources available throogh satellite canmunicatirns netwcrks. Werking in teams, students will use a variety d canputer programs to simulate gravity in various envirrnments, logging infamation aboot each envirrnment into a spreadsheet using the graphing fundioo. They will use a wcrd processcr to reard and analyze their observatirns. Students will use telec:cmmunicatirns sdtware to seek advice from a NASA scientist atout findings frcrn their simulation studies and the relationship between these simulations and actual NASA expeditirns. They will prepare a aief video presentatirn, desaiang their experiences, to help other students understand gravity. The skills to implement videcxiisc instructirn and authcring programs will be taught in the Integrated Scttware Applicatirns and Hypermedia ccmputer cuurses. 2. Applied Mathematics As displayed in the Applied Mathematics box of the chart on page---, all grade 7 magnet students wiJt take Aera
pace Mathematics. Beginning in grade 8, two cuurse sequmce routes are depicted: A Applied Mathematics I (8) Applied Mathematics II (9) Desaiptive Geomeay (10) Technical Algetra (11) Quantitative Literacy fer Aerospace (12) n Technical Algebra I (8) Descriptive Geaneay (9) Technical Algetra II (10) Advanced Algebra/Trigonanetry (11) Calculus (12) Ca.irse sequence A was devised fer learners who have generally an eighth-grade, pre-algetra mathematics a:mpetency level. Coorse sequmce B captures the student whose perfcrmance indicates readiness fer algetra in grade 8. Beth CDJrses antain required antent knowledge which is supplemented ~ engineering er aviatirn related skills and activities. The engineering and aviatirn applications have been develq:,ed with industry and university persamel, are relevant to careers emphasized in this program, and are linked to the Aerospace Science and occupational curriculum Coorse antent is desaibed rn pages __ . 3. Computer Technol~y and the Computer Techndogy Latoratay Course crntent in Integrated Scttware Applicatirns, Logo.vriter Rolxtics, Hypercard/ Hypermedia, Aerospace Pre-CAD, and Hi-Tech Presentatirn will give students the backgroond of knONledge and skills needed to be competent a:mputer users in the Engineering Techndogy and Airway Science COJrsewcrk
in the Techndogy Lab 2000
and at the wcrksite. Canputer COJrse content reflects a se::iuential program d skill development and task ccmplexity invdving the learning of sdtware applications, specific programs, and multimedia equipment. To implement the OJUrsewcrk, this magnet program requires a ccmputer labcratay at the individual magnet sites. Canputer cwrsewcrk will require ooe ccmputer per student in a class. To accanodate the typical grade 7-10 class size, 30 Macintosh LC Ifs, 3 Laserwriter Ifs and 2 Imagwriter Ifs, Telea:rnmunications hardware/scttware, a Macintosh Quadra file server system, and Appletalk Netwerk (Ethernet) hardware will be needed for each lab. All programs will be stered oo the Quadra fileserver. Printers, the Quadra file server, and individual Macintosh ccmputers will be c:a,nected together into a network system. Via the network, students will acces.s and c:a,trd cx:ntent, applications, and infamatioo in the areas ci systems simulattoo, wcrd processing, Lego Logq rd:xJti~ and publishing. They will produce their own presentatioo material by importing so.md, graphi~ digitized phctographs to hypercard or laserdisc stacks ci their CJINn creatioo, and receive suppcrting visual imagery oo adjacent video mooiters. The 1~ netwerk wilt allow teachers and students to share files, scitware, and printers. In additioo, dassrcx:ms within the school, the fair magnet schools, and the museum will be tied In together to the Prqect Directer's Office allowing for additional netwerk services like electronic mail and database sharing that will be widely utilized fer ccilalxrative prqects amo.ing the Aerospace Magnet Schcds. Educational benefits of the Aerospace Magnet Netwcrk include: Group document editing and management (student and teacher prqects). Screen sharing giving the Prqect Director and teacher the capaality to view any Macintosh mooiter oo the netwerk. Central database fer scitware documents, and aerospace magnet information. Calendaring fer magnet and museum events. Electronic Mail to speed up ccmmunicaticn and reduce paper. Hypermedia, Hi-Tech Presentatioo cwrse hardware requirements indude an Apple One Scanner, Apple CD 150, Videodisc Player, Macreccrders, Video recorders, Cama:rders, Video Digitizer, Roster Opps Board, and speakers. This hardware will be erganized Cl'\ teacher and student werkstations. The ccmputer curriculum goals and oojectives statements found en page ---, and project o.itlines located in the appendix illustrate hew students will apply knowledge/skills attained within the disttid and aerospace techndogy curriculum in multimedia, team projects. The lessoo design and project ootlines spell rut the suqect area concepts er skill extensioos, the scttware program and applicaticn, student team activities, and product. Fer example, students will use canputer applic.atirns in spreadsheets to answer "What If?" questirns, to test hypctheses, and to ca1struct famulas pertaining to mathematical and logic.al functirns. Students will e,cpress ideas via wcrd processing and create simulatirns cr variws situatioos using hypercard. In progamming, students will prcx:iuc:e output in text, graphics, and rdxt actioos. They will use numeric and variables, arithmetic operates, and design appropriate errcr tapping rwtines. Instruction in the canputer coorsewak and integrated rumcular team projects will cane fran a Canputer Techndogy Specialist who will be a TECH member cr the Science/Math/TECH lnstructa Team Canputer Techndogy Specialists will use a single canputer with a large TV as a derna,stratioo device. They will preplan lessons a, the canputer and will reccrd the Jessa, using the VCR The Jessa, will be presented to students to actively invdve them in disoovery learning. Lesson segments may be replayed cr stepped as needed for disrussia, and darificatiai. Video benetits students' conceptual understanding cl mathematics and science applicatioos. Real cbject or events can be sha.vn fran several angles. perspectives, aders cl magnification and pcints cl view, such as flipping and rctattng shapes in geanetry. Video animation 1~ and canputer graphics will especially be used to introduce, explain, a reinface ooncepts. Ptia lessen planning using the canputer, TV saeen, and VCR enable the teacher to better JT\Cllita and adjust the teaming fa students and to give individualized help as needed during the Jessa,. The canputer techndogy instructiaial schedule will oonsist cl eight, 50-60 minute periods that will interface with the magnet block fJexibte schedule ootlined a, page ---. The cx:mputer labcratory will be cpened fa students to use befae schcd and at lunch. After schcd the a:mputer lab will be used fa parent education. The Madnt~ Product Registry (September 1992) p-ogram desaiptims, (in cx:x,sultatim with expert users), was used to identify software utility programs. All satware programs pia to purchase will be previewed by magnet teacher specialists in cx:x,junctfon with the Aeraspac:e Techndogy 0.1rrt0.1lum Scttware evaluatia, fains specially-designed for this p-qect will be a:rnpleted to dcx:ument 0.1rrt0.1tum relevance and prcblem-sdvtng capa}jlities. 4. Faeign LaniYap Japanese, Russian, German, French, and Spanish wilt be clfered beginning in grade 7. Currently, the CXJl"e rurria.llum for grades seven and eight does net emphasize foreign language The high school a.miailum requires 2 years of the same language. The Aerospace Techndogy Currirulutl\ thereta~ is providing students with the cppatunity to start a modern language early to L ' ... ,. - - ~ - -
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LRSD Occupational Areas of Focus Computer-Aided Design/Drafting Product Engineering Environmental Quality Assurance Job Descriptions Product Engineering DefWllon: The llnplementalion ol all ~ of manufacturing product and ll0ollng delign, COit, deCal P,odUCllon and ope,allan plant, ayatema and procedurNhnlthodt, qualty aaurance mlthodt, meteriall and procna apeclflcaliona, and problem rwoMion. Job Description: Production EnginMta adm.,..., tool Ind manufactlmg P,actlcN for. rna
o, projecl ~ ptOduc:t ..... At the tectinlcal level emphult It on dNlgn analytil, performance analyllt, 1Y11MM and p,ooedurN mlNI, geneaa1 problem lnvNlglon, and maleflalt and PfOCNa IIMeligldona. AJ. ll'le eriry lewl, .nons .. dlr9Cled to ad and con1n11 ~- ~ ........... Produclan e..., MlnllaclUtlng e..., UlltanEnginNr Compuw Aided 0..lgn Appllcatlona Definition: Computer Aided DNigrl appl:1ll111 lndude the UM ot advanced computar tools to a.A Ille unique geomeay ol Ille product at W9I a lpeclal tool UN (CAE) to delannine the adequacy ol Iha deelgn ll'ldlr apecllc GDlldlbii. Job DNcrlpllon: CA0,4CAE Engineen utlllza OOffltMrlzed work1tallon1 to create unique daalgna of Of ueocillacl wlttl product geometry. TheN ltaff 1Mfflber9 uaually nilled clNign englnNrt who er ... the product claligll In ,_, time on the tyllaffl. The potltion tor !hit encry 1ew1 .non 11 '9lalad to copying or repaallng Hitting product datiglll Uling 1h11 181M workat.ion. The open,or wll allo ba trained In ttle UN ol a CAE tool to perform analyllt ot dNlgn a,1lclN and glllMt crltical dnlgn data. All or thil _,,. II under the dlrecllon ot aenlor dNign 919,_,. and IUbmlaed to ll'lern for approval. Entry...i CAO e>p.alor Speciallat Tedlnlcal Profeaalonal T~I Oeeipr Dnlgn EnglnNr QuaUty Auuranc1 DefNllon: The degrM ol contormance by an item to governing crtena apec11caaoru, tellact company or oontractual Inspection ~tortpaefflc:,,..,._, pana, or atNmblN. Job DNcrtpclon: To provide manufacturing or englnMring aupport tulrt In accordance with customer, company, or pe,1w1 p,aduca qually apecllca&lona Ind requirements. ~ 0ualty Engineer Environmental Definition: Compliance with i:.cs.,.,, - local, -,ct company NNty, healtl, and enwotlMfllal regulallont . Jab DNcr1plo... ~ Englnaart--. In dlwlopment of anvtrol..,... p,cuction prog,ama and Operalona U w.11 U anhancement of a,nployae and management awarenftl of ~-,... and objec:INN. They prowie lal90n for organizallonal ~ to the OClfflffll.llil and lncMtry on enwoi.,... aahllt!N. M the tac:fln6oll and antry 1eYe1 eflorta a,e dlrec:lad to plant-wide tl&nrdout wute handllng and aaodated documentation regantl119 tranaportlng, llorlng, 0111i1M111.a.c, clwlup n prOONlfng d haZlrdout w. Hmfdcul Mlllrlal Hazlrdout S9ecia1i11 Matertal TNm LNdlr Enwoni'MIUII EngiMer enable them to achieve oral and written language fluency and proficiency 0v1er a period d six years. Magnet fcreign language cifetings will be scheduled as part d the eight class period day cxntained within the block schedule. An instructcr pod will be created among the university magnet partners. This magnet's fcreign language teachers will be selected fran the poo. 5. Engineering Technotqsy The Engineering Technology occupatirnal program majcr will prepare students for entry into tomcrrCM1s manufacturing engineering envirooment and postserondary programs. As the diagram a, the opposite page illustrates, four demand manufacturing engineering areas and the entry level technical and prctessiaial career path have been identified in rollabcration with state aerospace industries: product engineering, CAD, Quality Assurance, and Envirrnmental. Additonally, industry has defined jd:> titles and respa,sialities. These are also stated in the diagram The University ct Arkansas at Little Rock (UALR) and Scuthern Arkasas University TECH have aligned aitical cx:cupatia, needs with four engineering technology programs ct study - Mechanical, Manufacturing, Canputer, and Electrrnics. A a:mma, ccre ct engineering technology courses which pEmleate these fwr programs, and specialized courses pertinent to individual programs have been arranged into grade 9-12 CDUrse sequences. Students a:mpleting grade 9-12 course sequences with a graded C er better will receive up to 15 advance credits when a:ntinuing in one engineering technology program at UALR The Mechanical and Electraiics Engineering Technology Programs are two a fa.ir year progra~ fa which a student may earn either an Associate ct Science a- Bachelor ct Science degree. Manufacturing Engineering Technology and Canputer Engineering Technology are four-year Baccalaureate programs. Belo.v is a sample flo.v chart based a, the Arkansas Plan fa- TECH PREP, 2+4+2+2 which displays the Engineering Technology grade 9-12 sequence. The entire course sequence is sho.vn here tn relattrn to graduatia, requirements to facilitate a:mprehensicn a the entire program Pages --- desaibe a:ntent kno.vledge fa grades 9 and 10 coursewa-k. The Canmitment and Capacity secticn, page --, explains a:ntent knowledge fa- grades 11 and 12 coursewa-k. Grades 9 10 11 12 The Engineering Technology Flow Chart Courses= 1 unit unless shown as .5 unit m = Aerospace Technology Magnet Academic Core* Mechanical, Electronic, Manufacturing Eng. Tech. Math (m) Science (m) World History Intro. to Concurrent Engineering English Physical Ed. (.5) Health (.5) Math (m) Science (m) Computer-Aided Design (CAD) Applications or Government (.5) Manufaduring Eng. Tech. I or Global Studies (.5) Electronics Eng. Tech . .CAD I English Wor1<place Readiness (.5) Fine Arts (.5) Math(m) Advanced CAO or ' Sdence(m) Manufacturing Eng. Tech. II or American History Electronics Eng. Tech . .CAD II English Internship I Foreign Language (m) Math (m) Science (m) Fabrication Design Project or Applied Communica- Manufaduring Design Project or lion (m) Mechanical Systems Design Project Foreign Language (m) Internship II Speech Elective Computer Eng. Tech. Intro. to Computer Science Computer-Aided De-sign Applications Electronics Eng. Tech . .CAD I Programming for Engineering Majors Arkansas State Board of Education standards for Accreditation (1984) state that students will take 3 units of science and 2 units of mathematics or 3 units of mathematics and 2 units of science to meet high school graduation requirements. ' There are three requirements with this COJrsewcrk: a) Students must take the engineering techndogy rourses related to their engineering program majer, i.e. manufacturing, computer, mechanical, electrrnics. b) Ca.trses must be taken in the sequence shown oo the flo.v chart. c) Foor units (years) each cf mathematiQi and science are mandated fer attainment of Engineering Technology perfcrmance standards. This magnet will reflect current practices used in industry, including tha
e cf emerging techndogies. Th~e indude ccmputer numerical contrd (CNQ machinery, cx:rnputer-aided drafting and manufacturing( NCCAD/ NCCAM) software, todtng, robotics systems, printed circuit bead equipment, scanners, and plotters. The goal is fer students to wak in teams and e<perience real productioo, ooe which requires them to plan for, design, and produce a product, inccrpcrting the elements cf quality and envirooment prctectirn. A netwaked CAD labcratory cf 30 Madnta
h Quadras, three Laserwriter II printers, three platers, and two scanners will be set-up in a specially-designed facility that also includes drafting tables with track drafting mechanism
. The manufacturing and electrrnics facilities will each house fifteen (15) netwaked Macintosh Quadras, 2 Laserwriter printers, a scanner, and an integrated manufacturing cell of NC equipment and robotic systems with a::mputer link-ups. Additional instructional materials and equipment requirements include industrial measuring instruments, pnaimatic and hydraulic ccmpooents, and mechanisms trainers. Ccntent knCM'ledge is described in the next sectirn .. Engineering Technology instructers will ccme fran the program's university partners, industry, the schcd district, and the Metrcpditan Vocatirnal-Technical F.ducation Center. These instructors will also be assigned to a l\1ath/ Science/TECH Instructa Team and will teach classes per the bloc:k schedule desaibed on page---. 6. Aviation The Aviation program majas will be implemented in cdlabaation with Hendersa, State University, Southern Arkansas University TECH, the Federal Aviairn Administratioo, and Central Aying Service. There ae five artiwlated, curricular paths depicted a, page --- and delineated in the grade 9-12 flON chart shown a, the oppa
ite page: The Aviation Flow Chart Program Major g 10 11 12 1. Aviation General Aviation Powerplant Electric Circuit Powerplant Maintenance Machine Shop Theory & Analysis Systems and Technology Maintenance Components 2. Airway Introduction to Programming Fortran/Cobol Assembler Computer Aeronautics + Language Language and Science Lab Operating Systems 3. Airway Science Introduction to Programming Aircraft Systems Air Traffic Control Aeronautics + Language Theory lab 4. Aircaft Systems Introduction to Aircraft Systems Aircraft Aerodynamics + 5. Aeronautics + Theory Powerplant Performance lab Theory , Professional Introduction to Aircraft Systems Aircraft Private Pilot Pilot Aeronautics + Theory Powerplant Certification & Lab Theory lab All students take the same math, science, a::mputer techndogy oore as the Engineering Techndogy program students. Students ccntinue Aviatic::n Maintenanc:2 a.mirular path at Sa.lthem Arkansas University- TECH. Cwrsewak for all ether Aitway Science and Professic::nal Pilct program majas ccntinue at Hendersc::n State University. All students will take a c::ne year Aviatic::n course regarding Aviation Safety I Legislati en/ Trans.portation. All students will have flight training ccnduded by certificated flight instrudas under the guidelines c:i Federal Aviatic::n Regulatic::ns, parts 141 and 61. All Aviation coorsework will be taught at the Museum c:i Aviatioo History ~ Southern Arkansas University TECH and Hendersoo State University instrudas in a:xrdination with Central flying Servic:2 and the Federal Aviatioo Administratic::n. Instrudas will share the same students as members c:i Math/Science/TECH Instructor teams. Students will receive advance credits from the two universities for canpleting the Aviatic::n Magnet program. Cooditions and stipulations faadvance credit receipt are outlined in Artirulatic::n Agreements. This program has an infcrmation and guidance romprnent that will be implemented with industry, the universities, and the Aera
pace Technology career camselcrs. Through a camseling team made-up d professirnals frcrn each crganizatirn, students wilt be advised CJ the eca,omic and educaticnal benefits related to the engineering technology and avi atia, career path. This witl enable students to make soond career decisirns aoout which area to select as a program major. A six week, four hoor summer session wilt be held at the three magnet junicr high schods in 1994, and in all magnet sites in 1995. Any student attending the Aerospace Magnet site during the regular school year, inc:cming distic:t seventh graders to the magnet sites, and oot-CJ-district white students will be targeted fer Summer Schad enrollment. Summer magnet site enrollment will be within the 60 (~ack) - 40 (white) 'oa}anced range. Summer magnet enrollees will be required to sign an agreement c.cncurring with attendance stipulatirns. 7. SCANS Know-Hew SCANS America 2000 cxrnpetencies (as desaibed rn pages 27-28) will be integrated aC"OSs the Aeraspace Technology curriculum and aligned with the Accountal:ility System CJ measures and standards ot performance fer this magnet program. Students will learn the SCANS Know-How throughout mathematics, science, cxrnputer, and occupatirnal c.cntent
and in the more specialized oontexts a the technology laboratories and industry-oosed wcrk. Every student, therefcr~ will ccrnplete the magnet junior high school with an intrcx.1uc:tirn to wcrkptace Know-How. By age 16, magnet students will attain initial mastery in the SCANS Kna.v-Ha.v and be sufficiently praicient upa, canpletirn a this magnet program in grade 12. The instructional strategy employed fer attaining praidency is learning c.cntent while solving realistic proolems. Students and teachers will learn and apply kna.vledge in real-life situatirns, for exampl~ by participating in this magnet's industry internship program .. From: QUALITY CONNECTION SERVICES PHONE No. 310 598 5773 ,o, 'tv\o.c... ~ d, ~n 9-,v-ow'r'""'I Q Lc..-\L \--te \ ~ y Dec.10 1992 2:12PM P01 M. e...,s ::, ,"---1-e. \ K'e~W\-0\.~ r (.,} } r, ~-1.--t C.ar/1~ P"-Je,, o.,f~.. .. e.e \kfA ""I K,.~ 9 Dec. 10 1992 2 : 12PM P02 bm : QUALITY CONNECTION SERVICES PHONE Mo. 310 598 6773 ~~ 1996-97 the Aerosp~l<l.i\ll"et l-ligh School gcade 10-12 enrollment wlll be n.l capaclly which is ~pupils. The high s~houb<.?nrollmcnt c-uupleU with the grade 7-9 junior high enrollmen'Fe'!.'?.s the aerospace magnet has the potential lo serve 4,597 pupils. The magnet enrollment will reduce black isolation in three junior high schools. C. Interdistrict and Intradistrict Desegregation Measures 1. Background Information on the Court Order The only image that some people have of Little Rock is the one formed in the Pall of 1957 when Governor Orval Paubu!S defied a feut!ral manuatt! a1,d tried to use the Arkansas National Guard to keep nine black students from entering Central High School. In Cooper vs. Aaron (1958), the Supreme Court stated that "public opposition to desegregation of the races, no matter how deeply entrenched, could not be allowed to interfere with the full realization of the constitutional rights of black citizens." Twenty-four years later (1982), the Little Rock School District brought suit against North Little Rock and Pulaski County Special School District, claiming that the Constitution compelled the consolidation of the three districts into one governmental unit. n,is claim was rejected by the courts in 1985 and again in 1986
however, the courts held that interdistrict constitutional violations had occured and must be remedied. Over the course of the next three years, various remedial orders were entered and further appeals were taken to court. Then, in 1988 and 1989, in a sharp departure from the adversary bitterness that had marked this controversy for over thirty years
the parties, including the Joshua intervenors representing the injured class of black schoolchildren and citizens, LRSD, the North Little Rock School District (NLRSD), the Pulaski County Special School District (PCSSD), and the State of Arkansas (Arkansas State Board of Education), agreed to settle the case. 'they submitted to the District Court four comprehensive agreements covering both interdistrict and inttadistrict desegregation measures -- agreements referred to by the parties as the "settlement plans." They also submitted a separate but related document, called the "settlement agreement," settling the financial liability of the State of Arkansas. The United States Court of Appeals for the Eighth Circuit reversed this judgement on June 27, 1989, and directed the District Court to adjust the boundary between the LRSD and PCSSD, to revise student attendance within each district to reflect the racial composition of the district, to maintain PCSSD's percent black student enrollment within the range of plus or minus 25% of the districtwide average of blacks by organizational FRIDAY, ELDREDGE & CLARK HERSCHEL H. FRIDAY. P .A . ROBERT V. LIGHT, P.A. WILLIAM H. SUTTON, P.A. JAMES W. MOORE A PARTNERSHIP OF INOIVIOUALS ANO PROFESSIONAL ASSOCIATIONS ATTORNEYS AT LAW BYRON M . EISEMAN, JR., P . A . JOE 0. BELL , P .A. JOHN C . ECHOLS, P.A. JAMES A . BUTTRY, P.A. FREDERICKS. URSERY, P . A . H . T. LARZELERE, P .A. OSCAR E. DAVIS, JR . JAMES C. CLARK, JR . . P.A. THOMAS P . LEGGETT. P.A. JOHN DEWEY WATSON, P . A . PAUL 8. BENHAM Ill, P . A. LARRY W. BURKS, P . A. A. WYCKLIFF NISBET, JR., P.A. JAMES EOWARO HARRIS, P.A. J. PHILLIP MALCOM. P .A. JAMES M. SIMPSO N , P .A. MEREDITH P. CATLETT, P . A . JAMES M , SAXTON, P .A. J. SHEPHERD RUSSELL Ill DONALO H. BACON, P .A. WILLIAM THOMAS BAXTER, P .A. WALTER A . PAULSO N II, P.A. BARRY E. COPLIN, P.A. RICHARDO. TAYLOR, P . A . JOSEPH B . HURST, JR., P .A . EL I ZABETH J . ROBBEN, P.A. CHRISTOPHER HELLER, P.A. LAURA HENSLEY SMITH, P . A . ROBERTS. SHAFER , P.A . WILLIAM M . GRIFF IN 111 , P. A. THOMAS N. ROSE , P.A. MICHAELS . MOORE DIANE S. MACKEY, P.A. WALTER M . EBEL Ill, P.A. Mr. Sam Jones 2000 FIRST COMMERCIAL BUILOINO 400 WEST CAPITOL LITTLE ROCK, ARKANSAS 72201-3493 TELEPHONE 601-378-2011 FAX NO . 601 -376 - 2147 December 9, 1992 DEC 1 0 \992 01.. o' -uo~er,.-r.aticn Monitoring ('.Ctl I .,., ~~ cl Mr. Steve Jones WRIGHT, LINDSEY & JENNINGS 2200 Worthen Bank Bldg. JACK, LYON & JONESt P.A. 3400 Capitol Towers 200 West Capitol Capitol & Broadway Little Rock, AR 72201 Mr. John Walker JOHN WALKER, P.A. 1723 Broadway Little Rock, AR 72206 Ms. Ann Brown Heritage West Bldg., Suite 510 201 East Markham street Little Rock, AR 72201 Re: Grant Application Dear Counsel and Ms. Brown: Little Rock, AR 72201 Mr. Richard Roachell MITCHELL & ROACHELL, P.A. 1014 West Third Little Rock, AR 72201 .:EVIN A . CRASS , P. A . WILLIAM A . WADDELL . JR., P.A. CLYDE TAB TURNER, P. A. CALVIN J . HALL. P . A . SCOTT J. LANCASTER, P .A. JERRY L. MALONE, P . A . M . GAYLE CORLEY, P . A . ROIERT I . EACH , JR., P .A. J. LEE IJROWN , P . A . JAMES C. I.A.KER , JR ., P. A . H . CHARLES GSCHWENO, JR .. P.A . HARRY A . LIGHT, P . A . SCOTT H . TUCKER JOHN CLAYTON RANDOLPH GUY ALTON WAD E PRICE C. GARONER THOMAS F. MEEKS J . MICHAEL PICKENS TONIA P. JONES DAVID D. WILSON JEFFREY H. MOO RE T . WESLEY HOLMES ANDREW T. TURNER SARAH J . HEFFLEY JOHN RAY WHITE DAVID M . GRAF PAMELA 0. CORKER CARLA G. SPAINHOUR JOHN C. FENDLEY, JR. COUNIH WILLIAM J, SMITH WILLIAM A. ELDREDGE, JR., P .A. B.S. CLARK WILLIAM L. TERRY WILLIAM L. PATTON. JR., P . A . WRITER'S DIRECT NO. (501) 370-1506 370-1506 I have enclosed a copy of the grant application I received today from Gail Quinn. CJH/k Enc c-v DEC 1 0 1~2 Office of Desegregaiion Monitoring Little Rock School District Aerospace Technology Magnet Program Absbad The Little Rock Schoo District's Magnet Schools Assistance grant applicatia, presents a dynamic plan fer implementation of a grade 7-12 Aerospace Techndogy Magnet Program in three (3) junior high schoos and the new Aeraspace Educatirn Center. The Center combnes a museum of aviatirn histcry with a grade 7-12 Aerospace Technology Schoo a, a 19.8 acre tract at the Little Rcx:k RegirnaJ Airpcrt adjacent to the main terminal, Falca, Jet, and Arkansas Aerospace. Collabcratively develcped with the Aerospace indusmes-1> and Campaign Leadershipb>, foor universitiescl and the U.S. Department ci Educatia, Federal Aviatia, Administratirn (FM), this magnet program targets the readying of students fer immediate employment and/er pa
tsecondary education In either engineering technology er airway science. As illustrated belc,.v, students are prooded a wide range ci choices fer c.areer develcpment in a,e of nine areas at an entry, technidan, er prdessirnaJ level: Aerospace Engineering Technology Aviation Airway Science (FM) Manufacturing Airway Canputer Science Computer Science Airway Sciente Management Mechanical Aircraft Maintenance Electronics Aircraft Systems Protessiaial Pilct Majer Arkansas aerospace employers and the FM have identified techndogical occupatia,s and the skill base students need for future empl~ent. LRSD has inoorperated the skill base into a highly integrated program/ ca1rse sequence ccnsisting ci Academic lnstructicn, Work-Based Leaming, Werksite Experience, and Information and Guidance. All magnet students will take a CXJTlmal academic cxre of sequenced a,.irses whidl include six years ci applied mathematics and science (mere than required for graduation) keyed to prcx:1uc:t engineering and flight/space cmcepts, two er more years ci a language significant to our glcbal arnpetitive marketplace sudl as Japanese er German
and Applied Canmunication. In CXlllpUter netwerked laooratcri~ students will access and a:rttrd oontent, applicatirns, and infcrmatia, in the areas ct robotics, bio astrooautics, systems simulatia,, CAD/CAM, publishing, werd pr~ing, teleccmmunicaticns, material science, and aercx:1ynamics. Students will produce presentatia, material ~ importing soond, graphics, digitized phctographs to hypercard er laserdisc stacks ci their c,.vn creatiai. In Science, students will ccnduct hands-on investigatia,s, manipulate scientific instruments, and cdlec:t:/ analyze data a) Arkansas Aer~ Rohr Industries. Falaxt Jet, Midmast. Ca,tral Flying Service b) Membership attached c) l'niversities of Arkansas at Little Rock and Pine Bluff, Hatderson State University, Southern Arkansas University TECH. using the critical thinking skills d cbservatioo, canmunicating, comparing. crdering, categorizing. relating. inferring. and applying. Specialized curricula related to each ci the nine career cpticns has been developed to meet OCOJpation specific kno.vledge and emerging tec:hndogy requirements. Students will be trained on the job throogh partidpatioo in industry and aitpcrt-based internship programs. All students will be educated to higher levels than ever betae. The vehide for OCOJpattcnal certiftcattai is achievement ci the U.S. Department of Labcr's SCANS (Seaetary's Canmissia, ci Achieving Necessary Skills) five workplace ccmpetendes, e.g. Resources, lnterperscnal Skills, Infamation, Systems, and Technology
and the earning of C.ertificates ci Initial Mastery (CIM). An assessment system based en SCANS Kno.v-Ho.v and cumulative resume, which reports results, will be the permanent recxrd a genuine student attainment of CIM and future employment. In addition, program c:anpletion in a chosen cxx:upatiaial majcr will enatie students to receive advance university aedit and ccntinuatia, of the engineering a airway science career track throogh associate a science and baccalaureate degree programs. As yoo cx:nsider the fine merits a this highly cx:ilabcrative magnet program, please keep in mind the thoosands a students it Will enable to gain state-of-the-art techndogical skills, en~rage to ccntinue their educatim thra.agh Articulatia, Agreements, and to fill key manufacturing and FAA jc:bs so vital to the future ct this nation to c:anpete in the wald market. I. Background Informati_on A. Greater Metropolitan Little Rock Greater Little Rock's four county Metropolitan Statistical area (MSA) is the center of the second fastest growing region in the United States. Its central location is within 550 miles of forty percent of the United States buying power and population. The $1.3 billion dollar Arkansas Navigation System, one of the nation's largest water development projects, is a 445 mile waterway providing year-round access to ports on the Arkansas River from the Mississippi River to Tulsa, Oklahoma. The 1,500 acre port with its industrial harbor Foreign Trade Zone - 14, and the United States Customs Port of Entry are an indication of the increasing importance of Little Rock's linkage to ports worldwide. All are in close proximity to Adams Field, Little Rock's airport. The city's rich mixture of historic architecture and new development is attracting new residents. Little Rock is seeing growth and revitalization unparalleled in the city's history. ' Little Rock is on the move. Fueling this revitalization are the aerospace industries, the Arkansas Aviation Historical Society, the Governor's Aerospace Task Force, and institutions of higher education. Some of the world's most successful aerospace companies are located here: McDonnell Douglas, Rohr Inc., Arkansas Aerospace (a subsidiary of British Aerospace), Falcon Jet owned by the French-based A vions Dassaut Brequet Aviation, MidCoast, and Central Flying Service. Numerous private and corporate aircraft dealers such as Aero-Commander, Piper, Beechcraft, and Cessna have facilities at the Little Rock Regional Airport. Little Rock Airforce Base is home to the largest C-130 aircraft training and airlift facility in the world. A number of major educational institutions serve Little Rock's M.S.A. By far, the largest of these is the University of Arkansas at Little Rock (UALR), enrolling more than 11,000 students in seventy-five undergraduate and forty-two graduate degree programs including Associate, Bachelor and Masters of Science Degrees in Engineedng Technology. The Graduate Institute of Technology (GIT) housed in the new Engineering Technology Center offers courses in mechanical, computer science, electrical and manufacturing engineering. Industries utilize GIT facilities for advanced research and graduate study. In 1991, the Arkansas Space Grant Consortium, under the leadership of GIT at UALR, received a four-year training grant award from the NASA National Space Grant College and Fellowship program. The primary purpose of the program i:
to educate and familiarize faculty and undergraduate and graduate students with aerospace fundamentals and NASA's research programs and opportunities. A secondary objective is to motivate K-12 students to excel in math and science courses necessary for entrance into aerospace programs at the universities and high tech positions in industry. Henderson University, in coordination with Central Flying Service, conducts one of the few aviation degree programs in the nation. The University's Department of Aviation provides four-year programs in Airway Science Management,Airway Computer Science, Professional Pilot, and Aircraft Systems Management. The Arkansas Aviation Historical Society serves the entire state as the focal for the involvement of Arkansas' aerospace industries in community affairs, education, and economic development. In 1989, the Society, executives of aerospace companies, the Little Rock School District, and UALR came together to form the Aerospace Education Center Campaign Leadership. The unprecedented public/private partnership has planned an Aerospace Education Center. As the architect's drawing illustrates, the Center combines a museum of aviation history with an Aerospace Technology Magnet High School on a 19.8 acre tract at the Little Rock Regional Airport adjacent to the main terminal, Falcon Jet, and Arkansas Aerospace. The facility will cover 200,000 square feet, including common areas used by both the museum and high school such as the library, cafeteria, and theatre/ auditorium. The upper level of the museum will function as an educational resource for adult programs, and outreach for schools, state and nationwide through a satellite television uplink provided by the Arkansas Electric Cooperatives. The most comprehensive and largest technical and historical aviation and aerospace library collection outside of the Smithsonian's National Air and Space Museum was acquired for the Arkansas Museum of Aviation History. Virtually every civil and military aircraft, rotocraft, and spaceship designed and constructed throughout the world is represented in the collection by technical specifications, photographs, and historical descriptive information. There are well over 5,000 books, 50,000 journals, 200,000 photographs and transparancies, hundreds of rare collectable items signed by famous pilots and aviation personalities, original paintings, scale aircraft models, and unique aircraft parts. The Society has raised over five million dollars in gifts and pledges toward construction of the aviation history museum. The Llttle Rock School District has budgeted six million dollars for the construction of the Aerospace Technology Magnet High School from funds approved by voters at a property tax election in 1990. The Aerospace Education Center Campaign Leadership believes that Greater Little Rock's future rests on the vitality of its public education system. At all levels of the public education system, educators and industry must develop programs which give students the knowledge and skills that enable them to reach their full economic potential. While the Center will prepare students for aerospace careers, it will also focus the Central Arkansas community on commitment to excellence in education. In March 1819, Arkansas became a territory and the Arkansas Post, the state's fir
This project was supported in part by a Digitizing Hidden Special Collections and Archives project grant from The Andrew W. Mellon Foundation and Council on Library and Information Resoources.