Thursday, December 7, 2023

Industrial Engineering Programs - USA - Department Chairs and Program Coordinators

New.

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-----------------------

For 2024


https://www.collegefactual.com/majors/engineering/ie-industrial-engineering/rankings/top-ranked/



https://www.collegefactual.com/majors/engineering/ie-industrial-engineering/rankings/top-ranked/southwest/

Texas - Arizona - Oklahoma  - New Mexico


2024 Best Industrial Engineering Schools in Texas

9

COLLEGES IN TEXAS

927

IE DEGREES AWARDED

$65,949

AVG EARLY-CAREER SALARY


https://www.collegefactual.com/majors/engineering/ie-industrial-engineering/rankings/top-ranked/southwest/texas/



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1. Georgia Institute of Technology - Main Campus

 

 Atlanta, Georgia


Santanu Dey

Breadcrumb

Home 

Santanu Dey

Associate Chair for Graduate Studies

Anderson-Interface Professor

https://www.isye.gatech.edu/users/santanu-dey

https://www.isye.gatech.edu/user/128/contact


santanu.dey   @isye.gatech.edu


Office: Groseclose, Rm 443

765 Ferst Dr, Atlanta GA 30332


Phone:+1 (404) 385-7483

Fax:+1 (404) 894-2301


Alan Erera

https://www.isye.gatech.edu/users/alan-erera

https://www2.isye.gatech.edu/faculty/Alan_Erera/ 



Associate Chair for Research

Manhattan Associates/Dabbiere Chair

Professor


alan.erera   @isye.gatech.edu

Location: 223C Groseclose Building

Office: (404) 385-0358 Direct: (404) 496-8871 Fax: (404) 894-0426


Edwin Romeijn

https://www.isye.gatech.edu/users/edwin-romeijn

Edwin Romeijn

H. Milton and Carolyn J. Stewart School Chair

Professor

https://edwin-romeijn.isye.gatech.edu/contact   send message


Chen Zhou

https://www.isye.gatech.edu/users/chen-zhou

Chen Zhou

Associate Chair for Undergraduate Studies

Associate Professor

https://sites.gatech.edu/chen-zhou/

https://sites.gatech.edu/chen-zhou/contact/


He has given keynote talks on “Logistics Education,” at The First Sino-US Logistics Forum in 2005, “The Success of ISyE in Georgia Tech,” at Industrial Engineering Greater China Conference in 2012, “The Future of Industrial Engineering from a Rearview Mirror,” at 3rd International Asia Conference on Industrial Engineering and Management Innovation in 2012, “The Industrial Engineering Education in the US – design strategies and examples,” at First National Industrial Engineering Education Forum, 2013, and “ISE and Sustainability,” IISE Regional Conference in 2018.






 

2. University of Michigan - Ann Arbor

 

 Ann Arbor, Michigan


XIULI CHAO

Ralph L. Disney Professor, Master’s Program Director

xchao    @umich.edu


MARINA EPELMAN

Professor, Associate Chair of Graduate Studies

mepelman    @umich.edu

(734) 763-2189


JULIE SIMMONS IVY

Department Chair, Professor

jsivy    @umich.edu

734-647-5592


MARIEL LAVIERI

Associate Professor, Associate Chair of Undergraduate Studies

lavieri    @umich.edu

(734) 647-0872


SIQIAN SHEN

Professor

siqian   @umich.edu

(734) 764-5126



University of California

Berkeley, California 94720-1777

https://ieor.berkeley.edu/faculty/



Ilan Adler

ilan adler 2015 1

Professor

Head MEng Advisor

Industrial Engineering and Operations Research

Ph.D. Stanford University, 1970, Operations Research

4183 Etcheverry Hall

(510) 642-4987

E-mail: ilan(at)berkeley.edu   ilan    @berkeley.edu

https://ieor.berkeley.edu/people/ilan-adler/


Anil Aswani

anil aswani 2015

Associate Professor 

Industrial Engineering and Operations Research

Ph.D. UCB, 2010 Electrical Engineering and Computer Sciences


4119 Etcheverry Hall

E-mail: aaswani(at)berkeley.edu   aaswani   @berkeley.edu

https://ieor.berkeley.edu/people/anil-aswani/


Alper Atamturk

unnamed 1

Professor and Chair

Industrial Engineering and Operations Research

Earl J. Isaac Chair in the Science and Analysis of Decision Making

Ph.D. Georgia Institute of Technology, 1998 Industrial and Systems Engineering

423 Sutardja Dai Hall

(510) 642-4559

E-mail: atamturk(at)berkeley.edu    atamturk   @berkeley.edu

https://ieor.berkeley.edu/people/alper-atamturk/


Rhonda Righter

rhonda righter 2015 0

Professor 

Industrial Engineering and Operations Research

Ronald W. Wolff Chancellor’s Chair in Industrial Engineering & Operations Research

Ph.D. UC Berkeley, 1986, Industrial Engineering & Operations Research

4187 Etcheverry Hall

E-mail: rrighter(at)berkeley.edu    rrighter    @berkeley.edu

https://ieor.berkeley.edu/people/rhonda-righter/



Northwestern University (McCormick) IL - Industrial Engineering Programs

Northwestern University Evanston, Illinois

https://www.mccormick.northwestern.edu/industrial/courses/



Seyed Iravani

Professor of Industrial Engineering and Management Sciences


Director of Graduate Studies

s-iravani    @northwestern.edu


Simge Küçükyavuz

Chair of Industrial Engineering and Management Sciences


David A. and Karen Richards Sachs Professor of Industrial Engineering and Management Sciences

 simge    @northwestern.edu



Janice Mejia

Associate Professor of Instruction of Industrial Engineering & Management Sciences


j-mejia    @northwestern.edu


3. Virginia Tech

 

 Blacksburg, Virginia


VIRGINIA TECH ISE IS THE #6 GRADUATE PROGRAM IN THE COUNTRY!

According to the U.S. News and World Report.

https://www.ise.vt.edu/


https://www.ise.vt.edu/people.html


Matt Earnest

Director, Center for High Performance Manufacturing (CHPM), ISE Learning Factory

Associate Professor of Practice

Matt Earnest

Matt Earnest

105 Durham Hall

(MC 0118)

1145 Perry Street

Blacksburg, VA 24061

mearnest    @vt.edu

540-231-1810

https://www.ise.vt.edu/people/faculty/earnest.html



Maury A. Nussbaum

H.G. Prillaman Professor, Assistant Department Head, and Graduate Program Director

CPE

Maury

Maury A. Nussbaum

521 Whittemore Hall

(MC 0118)

1185 Perry Street

Blacksburg, VA 24061

nussbaum    @vt.edu

540-231-6053

https://www.ise.vt.edu/people/faculty/nussbaum.html




John P. Shewchuk

Associate Professor, Associate Department Head, and Undergraduate Program Director

P. Eng.

John P. Shewchuk

John Shewchuk

259 Durham Hall

(MC 0118)

1145 Perry Street

Blacksburg, VA 24061

shewchuk    @vt.edu

540-231-6656

https://www.ise.vt.edu/people/faculty/shewchuk.html



G. Don Taylor

Executive Vice Provost, and Charles O. Gordon Professor in ISE

G. Don Taylor

G. Don Taylor

250 Durham Hall

(MC 0118)

1145 Perry Street

Blacksburg, VA 24061

don.taylor    @vt.edu

https://www.ise.vt.edu/people/faculty/taylor.html


Eileen M. Van Aken

Professor and Department Head

Eileen Van Aken

253 Durham Hall

(MC 0118)

1145 Perry Street

Blacksburg, VA 24061

evanaken    @vt.edu

540-231-6656

https://www.ise.vt.edu/people/faculty/vanaken.html



 

4. Lehigh University

 

 Bethlehem, Pennsylvania

 

5. University of Southern California 

 Los Angeles, California


USC Viterbi Daniel J. Epstein Department of Industrial & Systems Engineering

3715 McClintock Avenue, GER 240

Los Angeles, CA 90089-0193

Phone: (213) 740-4893

Fax: (213) 740-1120

Email: isedept    @usc.edu

USC Viterbi Daniel J. Epstein Department of Industrial & Systems Engineering


https://ise.usc.edu/people/


Maged M. Dessouky

Department Chair, Department of Industrial and Systems Engineering

Daniel J Epstein Department of Industrial and Systems Engineering

Spatial Sciences Institute


OFFICE

GER 240

Ethel Percy Andrus Gerontology Center

3715 McClintock Ave., Los Angeles, CA 90089

USC Mail Code: 193


CONTACT INFORMATION

(213) 740-4891

maged    @usc.edu



 

6. Purdue University - Main Campus

 

 West Lafayette, Indiana


https://engineering.purdue.edu/IE


Young-Jun Son

James J. Solberg Head and Ransburg Professor of Industrial Engineering

+1 765-49-62312

yjson     @purdue.edu




Patrick Brunese

Assistant Head

765 49-49611

pbrunese    @purdue.edu




Leza Dellinger

Director of Operations

765 49-45444

lrdellin    @purdue.edu


https://engineering.purdue.edu/IE/people/Admin



 

7. Northeastern University

 

 Boston, Massachusetts

 

8. Clemson University

 

 Clemson, South Carolina

 

9. Texas A&M University - College Station 

 College Station, Texas


https://engineering.tamu.edu/industrial/profiles/index.html#Leadership


Lewis Ntaimo

Professor, Industrial & Systems Engineering

Department Head, Industrial & Systems Engineering

Sugar and Mike Barnes Department Head Chair, Industrial & Systems Engineering

Office: ETB 4029

Phone: 979-845-5535

Email: Ntaimo   @tamu.edu


Joe Geunes

Professor, Industrial & Systems Engineering

Marilyn and L. David Black Faculty Fellow, Industrial & Systems Engineering

Director of External Education Programs

Associate Department Head for Graduate Affairs, Industrial & Systems Engineering

Office: ETB 4024

Phone: 979-862-9114

Email: geunes    @tamu.edu


Amarnath Banerjee

Professor, Industrial & Systems Engineering

Associate Department Head for Undergraduate Affairs, Industrial & Systems Engineering

Office: ETB 4041

Phone: 979-458-2341

Email: Banerjee    @tamu.edu



 

10. Pennsylvania State University - Main Campus

 

 University Park, Pennsylvania


https://www.ime.psu.edu/department/faculty-staff-list.aspx


Russell Barton


Senior Associate Dean for Smeal College of Business and Distinguished Professor of Supply Chain and Information Systems


210E Business Building


814-863-7289


rrb2   @psu.edu



Terry Friesz


Harold and Inge Marcus Chaired Professor


305 Leonhard Building


814-863-2445


tlf13    @psu.edu




Lisa Fuoss


Graduate Programs - Administrative Coordinator


343 Leonhard Building


814-863-1269


lkf1@psu.edu





Reese Harlow


Academic Program Assistant


113 Leonhard Building


814-865-7602


rph20   @psu.edu




Catherine Harmonosky


Associate Professor and Associate Department Head


304 Leonhard Building


814-865-2107


c1h   @psu.edu





Steven Landry


Department Head of Industrial and Manufacturing Engineering


310 Leonhard Building


814-863-6407


sjl6144   @psu.edu




Ling Rothrock


Professor and Graduate Program Coordinator


343A Leonhard Building


814-865-7241


lxr28   @psu.edu





Kelly Schiffer


Education Program Specialist


113 Leonhard Building


814-865-0972


knk5138   @psu.edu




Srinivas Subramanya Tamvada


Assistant Teaching Professor


349 Leonhard Building


814-865-7601


sst119  @psu.edu



 

11. Rensselaer Polytechnic Institute

 

 Troy, New York

 

12. Northwestern University

 

 Evanston, Illinois


https://www.mccormick.northwestern.edu/industrial/courses/



Seyed Iravani

Professor of Industrial Engineering and Management Sciences


Director of Graduate Studies

s-iravani   @northwestern.edu


Simge Küçükyavuz

Chair of Industrial Engineering and Management Sciences


David A. and Karen Richards Sachs Professor of Industrial Engineering and Management Sciences

 simge   @northwestern.edu



Janice Mejia

Associate Professor of Instruction of Industrial Engineering & Management Sciences


j-mejia  @northwestern.edu




 

13. Binghamton University

 

 Vestal, New York

 

14. North Carolina State University at Raleigh

 

 Raleigh, North Carolina

 

15. University of Wisconsin - Madison

 

 Madison, Wisconsin


DEPARTMENT

Industrial & Systems Engineering


Welcome to the intersection of engineering, people, and business.


Consistently ranked in the top-10 nationwide, the department offers the highest quality educational experience, world-class research opportunities, and cutting-edge facilities for work and study.



Laura Albert

David. H. Gustafson Dept. Chair of Industrial & Systems Engineering

Professor

laura   @engr.wisc.edu



Douglas Wiegmann

Associate Chair for Graduate Affairs

Professor

dawiegmann  @wisc.edu



Amanda Smith

Associate Chair for Undergraduate Affairs

Assistant Teaching Professor

amanda.smith  @wisc.edu



 

16. University of Washington - Seattle Campus

 

 Seattle, Washington

 

17. Kettering University

 

 Flint, Michigan


https://www.kettering.edu/academics/college-engineering/department-industrial-engineering

BSIE

https://www.kettering.edu/degree/bachelor/industrial-engineering-bachelor

 

18. University of Illinois at Urbana - Champaign

 

 Champaign, Illinois

 

19. Rutgers University - New Brunswick

 

 New Brunswick, New Jersey

 

20. Ohio State University - Main Campus

 

 Columbus, Ohio


https://ise.osu.edu/


Making Products Better Through Process Management and Innovative Design

brutus_enhanced_267x400_photobycedric.jpg

The ISE Department offers degrees in industrial and systems engineering (B.S., M.S. and Ph.D.). These degrees focus on the design, operation and management of complex systems, providing students with a blend of technical, management and  human-centered design skills. (Scroll down to see "Why ISE at Ohio State", in our own students' words.)


Diverse Career Opportunities: A degree in ISE offers career opportunities in a whole host of industries:  manufacturing and production * healthcare * finance * energy systems * retail and distribution * aviation * information technology * marketing * education.


In Demand:  According to the US Department of Labor’s Occupational Outlook Handbook, there are about 22,400 openings for industrial engineers each year.  And this profession is listed as having a ‘Bright Outlook’ in O*NET Online.


High Employment Rates: Our students have exceptional employment opportunities that add further value to this degree. For the past 3 years, each year over 82% of our graduates have been hired for jobs within 3 months of graduation.


GRADUATE PROGRAM


Shaw, Amy

Academic Program Coordinator, Integrated Systems Engineering

(614) 688-2107

shaw.229  @osu.edu


UNDERGRADUATE PROGRAM

Leslie Dowler

Dowler, Leslie

Senior Academic Advisor, Integrated Systems Engineering

(614) 292-6239

dowler.25   @osu.edu



DEPARTMENT CHAIR

Farhang Pourboghrat

Pourboghrat, Farhang

Professor, Integrated Systems Engineering

Professor, Mechanical and Aerospace Engineering

Chair, Integrated Systems Engineering

pourboghrat.2   @osu.edu





 

21. University at Buffalo

 

 Buffalo, New York


https://engineering.buffalo.edu/industrial-systems/news-events/newsletter.html


https://engineering.buffalo.edu/industrial-systems/people/faculty-directory.html


Rajan Batta

PhD, Massachusetts Institute of Technology

410 Bell Hall


Phone: (716) 645-0972


batta  @buffalo.edu


Associate Dean for Faculty Affairs and Recognition

School of Engineering and Applied Sciences

SUNY Distinguished Professor

Department of Industrial and Systems Engineering

School of Engineering and Applied Sciences

Research Topics: Operations research, production systems



Ann Bisantz, PhD

PhD, Georgia Institute of Technology

415 Capen Hall

Phone: (716) 645-8989


uge-dean  @buffalo.edu


Professor

Department of Industrial and Systems Engineering

School of Engineering and Applied Sciences

Dean of Undergraduate Education

University at Buffalo

Research Topics: Cognitive engineering; human factors in health care; human decision-making



Cecilia Martinez Leon, PhD, DSc, MBB

PhD, Texas Tech University; DSc, Monterrey Tech

400 Bell Hall

Phone: (716) 645-5596


cecimtz   @buffalo.edu


Associate Professor of Teaching

Director, Engineering Management Program

Department of Industrial and Systems Engineering

School of Engineering and Applied Sciences

Research Topics: Quality Management, Project Management, Lean Systems Engineering and Engineering Education. Overall, my research interests lie in identifying, articulating, and integrating engineering and management principles for developing effective product development and continuous improvement deployment frameworks for successful and sustained performance excellence.



Victor Paquet, ScD

ScD, University of Massachusetts, Lowell

323 Bell Hall

Phone: (716) 645-4712


vpaquet   @buffalo.edu


Chair

Professor

Department of Industrial and Systems Engineering

School of Engineering and Applied Sciences

Research Topics: Universal design, human performance in disability, occupation ergonomics to promote health


Moises Sudit, PhD

PhD, Purdue

B20B Lockwood


Phone: (716) 645-2423


sudit   @buffalo.edu


Associate Dean for Research and Graduate Education

School of Engineering and Applied Sciences

Professor

Department of Industrial and Systems Engineering

School of Engineering and Applied Sciences

Executive Director

Center for Multisource Information Fusion

Research Topics: Information fusion, military operations research


Jun Zhuang, PhD

PhD, University of Wisconsin-Madison

317 Bell Hall


Phone: (716) 645-4707


jzhuang   @buffalo.edu

Morton C. Frank Professor

Director of Graduate Studies

Department of Industrial and Systems Engineering

School of Engineering and Applied Sciences

Research Topics: Operations research, game theory, hazard response



 

22. Worcester Polytechnic Institute

 

 Worcester, Massachusetts

 

23. University of Pittsburgh - Pittsburgh Campus

 

 Pittsburgh, Pennsylvania

 

24. University of Miami

 

 Coral Gables, Florida

 

25. Auburn University

 

 Auburn, Alabama


https://eng.auburn.edu/insy/#gsc.tab=0


https://eng.auburn.edu/insy/people/#gsc.tab=0



Gregory Harris 

Department Chair

Professor

Director, The Interdisciplinary Center for Advanced Manufacturing Systems (ICAMS)

Associate Director for Digital Strategy, the National Center for Additive Manufacturing Excellence (NCAME)

 3312 Shelby Center

 gah0015   @auburn.edu     

 334.844.1407


Ph.D. Industrial and Systems Engineering, University of Alabama-Huntsville

M.B.A. Management-Operations, St. Edward's University

B.S. Industrial Engineering, Auburn University


LuAnn Carpenter 

Director, Student Program Assessment and Administration

 3301C Shelby Center

 simslua   @auburn.edu    

 334.844.1430


Ph.D. Industrial and Systems Engineering, Auburn University

M.I.S.E. Industrial and Systems Engineering, Auburn University

M.S. Applied Statistics, Georgia Institute of Technology

B.S. Engineering Economic Systems, Georgia Institute of Technology


Sa'd Hamasha 

Associate Professor

Graduate Program Officer

 3301H Shelby Center

 smh0083   @auburn.edu            

 607.768.8580


Ph.D. Industrial and Systems Engineering, Binghamton University

M.S. Industrial Engineering, Jordan University of Science and Technology

B.S. Mechanical Engineering, Jordan University of Science and Technology





 

26. Iowa State University

 

 Ames, Iowa

 

27. SUNY Maritime College

 

 Throggs Neck, New York

 

28. California Polytechnic State University - San Luis Obispo

 

 San Luis Obispo, California

 

29. University of Minnesota - Twin Cities

 

 Minneapolis, Minnesota

 

30. University of Oklahoma Norman Campus

 

 Norman, Oklahoma

 

31. New Jersey Institute of Technology

 

 Newark, New Jersey

 

32. Florida State University

 

 Tallahassee, Florida

 

33. The University of Tennessee

 

 Knoxville, Tennessee

 

34. Rochester Institute of Technology

 

 Rochester, New York

 

35. University of Massachusetts Amherst

 

 Amherst, Massachusetts

 

36. University of Illinois at Chicago

 

 Chicago, Illinois

 

37. Arizona State University

 

 Tempe, Arizona

 

38. Milwaukee School of Engineering

 

 Milwaukee, Wisconsin

 

39. University of Houston

 

 Houston, Texas

 

40. Oregon State University

 

 Corvallis, Oregon

 

41. University of Connecticut

Storrs


42. Bradley University

Peoria


43. University of San Diego,

San Diego, California


44 University of Iowa,

Iowa City


45 Kansas State University, 

Manhattan, Kansas


46. Texas Tech University

Lubbock


47. Oklahoma State University, Main Campus

Stillwater


48. University of Central Florida

Orlando


http://www.iems.ucf.edu


Waldemar Karwowski

Pegasus Professor and Chairman

wkar@ucf.edu


https://iems.ucf.edu/about-us/welcome-2/



49. University of Missouri - Columbia


50 San Jose State University

San Jose

https://www.collegefactual.com/majors/engineering/ie-industrial-engineering/rankings/top-ranked/p6.html


51. University of South Florida - Main Campus

 

 Tampa, Florida

 

52. Louisiana State University and Agricultural & Mechanical College

 

 Baton Rouge, Louisiana

 

53. University of Rhode Island

 

 Kingston, Rhode Island

 

54. Wayne State University

 

 Detroit, Michigan

 

55. West Virginia University

 

 Morgantown, West Virginia

 

56. University of Arkansas

 

 Fayetteville, Arkansas

 

57. University of Arizona

 

 Tucson, Arizona

 


58. University of Louisville

 

 Louisville, Kentucky

 

59. The University of Texas at Arlington

 

 Arlington, Texas

 

60. Saint Ambrose University

 

 Davenport, Iowa

 

https://www.collegefactual.com/majors/engineering/ie-industrial-engineering/rankings/top-ranked/p7.html


61. Mississippi State University

 

 Mississippi State, Mississippi

 

62. University of Alabama at Huntsville

 

 Huntsville, Alabama

 

63. Ohio University - Main Campus

 

 Athens, Ohio

 

64. Western Michigan University

 

 Kalamazoo, Michigan

 

65. Wichita State University

 

 Wichita, Kansas


https://www.wichita.edu/academics/engineering/ime/index.php



Dr. Krishna Krishnan

Professor and Chair


krishna.krishnan@wichita.edu


(316) 978-5903


Dr. Cindi Mason

Assistant Teaching Professor and Undergraduate Coordinator


cindi.mason@wichita.edu


316-978-5915


Maria Lucas

Student Academic Success Advisor


maria.lucas@wichita.edu


(316) 978-3513





 

66. Northern Illinois University

 

 Dekalb, Illinois

 

Overall Quality


67. California State Polytechnic University - Pomona

 

 Pomona, California

 

68. New Mexico State University - Main Campus

 

 Las Cruces, New Mexico

 

69. North Dakota State University - Main Campus

 

 Fargo, North Dakota

 

70. University of Wisconsin - Platteville

 

 Platteville, Wisconsin

 

71. Southern Illinois University Edwardsville

 

 Edwardsville, Illinois

 

72. Texas State University - San Marcos

 

 San Marcos, Texas

 

73. North Carolina A & T State University

 

 Greensboro, North Carolina

 

74. Louisiana Tech University

 

 Ruston, Louisiana

 

75. Oakland University

 

 Rochester Hills, Michigan

 

76. Kent State University at Kent

 

 Kent, Ohio

 


77. The University of Texas at El Paso

 

 El Paso, Texas

 

78. Morgan State University

 

 Baltimore, Maryland

 

79. Youngstown State University

 

 Youngstown, Ohio



80. University of Texas at Austin


Graduate Coordinator

512-471-1136

go@me.utexas.edu


81. COLUMBIA UNIVERSITY IN THE CITY OF NEW YORK


Department of Industrial Engineering and Operations Research

https://ieor.columbia.edu/people/ieor-faculty



Ton Dieker

Associate Professor; Vice Chair

MY CONTACT INFO

210K Innovation Hub

 2128530683

 dieker@columbia.edu



https://ieor.columbia.edu/content/ton-dieker


Jay Sethuraman

Professor; Chair

MY CONTACT INFO

326 Mudd

 2128544931

 jay@ieor.columbia.edu


https://ieor.columbia.edu/content/jay-sethuraman



82. 






Mayank Singh  1st degree connection1st

Lean consultant || Process Excellence and improvement ll Industrial Engineering ll Ex-TASL

https://www.linkedin.com/in/mayank-singh-718b23137/

Gemba Concepts


University of Petroleum and Energy Studies

Ahmedabad, Gujarat, India  Contact info

496 connections

UPESUPES

Bachelor of Technology (B.Tech.), Industrial EngineeringBachelor of Technology (B.Tech.), Industrial Engineering

2014 - 2018

 



Ud. 7.12.2023

Pub. 11.9.2023

Posted by at No comments:
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Industrial Engineering - Productivity Engineering in Software Engineering

 Defining Productivity in Software Engineering


Stefan Wagner & Florian Deissenboeck 


Chapter


Open Access


First Online: 08 May 2019


https://link.springer.com/chapter/10.1007/978-1-4842-4221-6_4


1979, Albrecht introduced function points to express the amount of functionality of an information system rather than the size of its code. Based on the specification of a system instead of on its implementation, function points were designed to support early development effort estimation and to overcome limitations inherent to the measurement of LOC, e.g., comparability between different languages. Function points provide a basis for productivity measures such as function points per week or work-hours per function point.


Another aspect related to productivity brought in by agile development was the counting of story points and the calculation of velocity as the number of story points per sprint. However, many proponents of agile development recommend not to use this measure of velocity as a productivity measure because it can lead to unwanted effects. 


Our starting point is Tangen’s [12] Triple-P-Model, which is a well-established model in knowledge work research to differentiate productivity, profitability, and performance as well as the programming productivity Wikipedia article (https://en.wikipedia.org/wiki/Programming_productivity). Especially in software engineering, efficiency is used instead of productivity; we also discuss it and differentiate it from effectiveness. Finally, following Drucker [8], we include a short discussion on the influence of quality on productivity. We discuss each of these terms separately in the following sections and will integrate them afterward.



Performance

The term performance is even broader than productivity and profitability and covers a plethora of factors that influence a company’s success. Hence, well-known performance control instruments such as the Balanced Scorecard [14] do include productivity as a factor that is central but not unique. Other relevant factors are, for example, the customers’ or stakeholders’ perception of the company.


Efficiency and Effectiveness

Efficiency and effectiveness are terms that provide further confusion as they are often mixed up themselves; additionally, efficiency is often confused with productivity. The difference between efficiency and effectiveness is usually explained informally as “efficiency is doing things right” and “effectiveness is doing the right things.” While there are numerous other definitions [12], an agreement prevails that efficiency refers to the utilization of resources and mainly influences the required input of the productivity ratio. Effectiveness mainly aims at the usefulness and appropriateness of the output as it has direct consequences for the customer.


There is still a lot of work to do until we can have a clear understanding of productivity in software engineering. The complexity of capturing good knowledge work is an obstacle in general to unambiguously measuring the productivity of such work. We hope that at least our classification of the relevant terms and the resulting PE Model can help to avoid confusion and to focus further efforts.



UNDERSTANDING SOFTWARE PRODUCTIVITY

WALT SCACCHI

Information and Operations Management Department

School of Business Administration, University of Southern California, Los Angeles, CA 90089-1421, USA

(Appears in Advances in Software Engineering and Knowledge Engineering, D. Hurley (ed.),     Volume 4, pp. 37-70, (1995). December 1994

https://ics.uci.edu/~wscacchi/Papers/Vintage/Software_Productivity.html

What affects software productivity and how do we improve it? This report examines the current state of the art in software productivity measurement. In turn, it describes a framework for understanding software productivity, some fundamentals of measurement, surveys empirical studies of software productivity, and identifies challenges involved in measuring software productivity. A radical alternative to current approaches is suggested: to construct, evaluate, deploy, and evolve a knowledge-based `software productivity modeling and simulation system' using tools and techniques from the domain of software process engineering.

Summary of Software Development Productivity Drivers

The attributes of a software project that facilitate high productivity include:

Software Development Environment Attributes:


Fast turnaround development activities and high-bandwidth processing throughput (may require more powerful or greater capacity computing resources)

Substantial computing infrastructure (abundant computing resources and easy-to-access support system specialists)

 Contemporary software engineering tools and techniques (use of design and code development aids such as rapid prototyping tools, application generators, domain-specific (reusable) software components, etc., used to produce incrementally development and released software products.)

System development aids for coordinating LSS projects (configuration management systems, software testing tools, documentation management systems, electronic mail, networked development systems, etc.)

 Programming languages with constructs closely matched to application domain concepts (e.g., object-oriented languages, spreadsheet languages)

 Process-centered software development environments that can accomodate multiple shifting patterns of small group work structures

Software System Product Attributes:


Develop small-to-medium complexity systems (complexity indicated by size of source code delivered, functional coupling, and functional cohesion)

 Reuse software that supports the information processing tasks required by the application

 No real-time or distributed systems software to be developed

 Minimal constraints for validation of data processing accuracy, security, and ease of alteration

 Stable system requirements and specifications

 Short development schedules to minimize chance for project circumstances to change

Project Staff Attributes:


Small, well-organized project teams. Large teams should be organized into small groups of 3-7 experienced developers, comfortable working with each other

 Experienced software development staff (better if they are already familiar with application system domain, or similar system development projects)

 Software developers and managers who collect and evaluate their own software production data and are rewarded or acknowledged for producing high data value software

 A variety of teamwork structures and the patterns of shifts between them during task performance.

The factors that drive software costs up should be apparent from this list of productivity drivers. Software cost drivers are the opposite of productivity drivers. For example, software without real-time performance should be produced more productively or at lower cost than comparable software with real-time performance requirements.

Also, it should be clear from this list that it is not always possible or desirable to achieve software productivity enhancements through all of the project characteristics listed above. For example, if the purpose of a project is to convert the operation of a real-time communications system from one computer and operating system to another computer-operating system combination, then only some of the characteristics may apply favorably, while others are inverted, occurring only as inhibitors. In this example, conversion suggests a high potential for substantial reuse of the existing source code. However, if the new code added for the conversion affects the system's real-time performance, or is spread throughout the system, then productivity should decrease and the cost increase. Similarly, if the conversion is performed by a well-organized team of developers already experienced with the system, then they should complete the conversion more productively than if a larger team of newly hired programmers is assigned the same responsibility.



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Wednesday, December 6, 2023

Industrial Engineering Guidelines for Facilities Designers

Industrial Engineering is Cost Reduction through Productivity Improvement.

Productivity improvement is getting more output from the same resources. Materials, machines and men are considered as the three important resources. Product design, facilities design and process design influence use of resources. The contribution of industrial engineers at design stage of products, facilities and processes can be in the form of guidelines provided to designers.


Guidelines for:

1. Technology Selection

2. Facilities (Equipment) Selection

3. Layout Choice - Assembly Line - Cellular Layout - Job Shop - Fixed Location

4. Layout Design

5. Maintenance Policy and Programs

6. Replacement Decisions.



Facilities Industrial Engineering

https://nraoiekc.blogspot.com/2020/05/facilities-industrial-engineering.html



Interesting Information is available in.

Kolmetz Handbook of Process Equipment Design

(Engineering Design Guidelines)

https://www.klmtechgroup.com/Engineering-Design-Guidelines.htm











Ud. 6.12.2023

pub. 3.12.2023

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Monday, December 4, 2023

News - Information for Inspection Operation Industrial Engineering Analysis for Productivity Improvement

New from the blog.
Top 0.1% of Publications on Academia.Edu.  
INTRODUCTION TO MODERN INDUSTRIAL ENGINEERING by Narayana Rao Kvss.
122 Pages - Pdf File.
Free Download.    



Role of IEs in Quality - Not Appreciated

Contribution to quality by IEs through process improvement route is not well documented. It is not appreciated in quality related articles.

As part of process chart analysis, industrial engineers analyze inspection operations for effectiveness and efficiency. They ask the effectiveness question. Does the current inspection method have purpose? (ECRS). What else will improve #quality? They search for alternatives from up-to-date knowledge bases and brainstorming sessions. They design more productive inspection and quality assurance systems for each operation in the process.

Shigeo Shingo explained the IE's contribution to quality better in his book, Study of TPS from IE Point of View.
Shigeo Shingo's TPS Book and Other Contributions - Read Chapter Summaries

Process Improvement using engineering knowledge to reduce cost through increasing productivity of machines and men by reducing machine time and man time is the main activity of industrial engineering.

Many other disciplines help industrial engineers to achieve their objectives. But the main discipline that is the foundation for IE is engineering of products and processes.


Lesson 132 of  Industrial Engineering ONLINE Course - Process Industrial Engineering Module - Inspection Operations Analysis and Improvement  Sub-Module of IE ONLINE Course.

Also Information for IE - Case 45 

Ubiquity of Industrial Engineering Principle of  Industrial Engineering

It is applicable to inspection activities of all engineering braches. 



Twitter Search



2020 – Metrology Year in Review

December 29, 2020
We look back over 2020 and highlight Metrology News articles that featured technologies that are shaping the future of manufacturing metrology along with exclusive interviews with industry experts.


Inspection for Quality Assurance - News and Articles


Do it. It is Real Engineering. Industrial Engineering is Engineering Primarily.

Find 5 new engineering developments every day in elements related to facilities, products and processes in your organization and assess their use for industrial engineering. 
Best Practices in #IndustrialEngineering 



2023


Computer vision startup UVeye adds Amazon fleet to its growing list of customers.
Amazon to Deploy Automated Inspections for 100,000 Delivery Vehicles
 UVeye claims that its technology is currently used to scan over 2 million vehicles and 20 million tires every year.
WRITTEN BY IanWright
PUBLISHED Oct 24, 2023

Augmented Reality- Based On-site Pipe Assembly Process Management Using Smart Glasses
Daeyoon Moon, Soonwook Kwon, Thomas Bock, Hyunglyul Ko
Pages 1-7 (2015 Proceedings of the 32nd ISARC, Oulu, Finland, ISBN 978-951-758-597-2, ISSN 2413-5844)
2015 Proceedings of the 32nd ISARC, Oulu, Finland



Vicivision measuring machine helps tractor maker

Trenton S.p.A. is a manufacturer focused mainly on making parts for machines and tractors used for agriculture.
Trenton measures shafts with a Vicivision optical measuring machine.
The company uses an M2018 Techno with a touch probe to measure the many different parts made there.
Parts up to 1,500 mm in length are produced and inspected on the Vici machine (using) the touch probe to measure keyway slots and planes. This machine measures parts 2,000 mm in length and 180 mm in width, giving Trenton the versatility  in measuring the mechanical components they produce. According to the company, it can measure a part in 93 seconds,


Audi begins roll-out of artificial intelligence for quality control of spot welds
01 July 2023


Artificial Intelligence for Quality Control of Spot Welds


Top Stories - January 2023 Metrology News Magazine


3D Scanning Improves Client Reporting and Quality Control of Transformer Tanks
 January 4, 2023



2022

Benefits of non-contact structured light 3D scanners.

By Capture 3D, a Zeiss Company

September 8, 2022

https://www.qualitymag.com/articles/97119-metrology-toolbox-options


Is it Possible to Measure Shaft, Form and Gear with an All-In-One Machine?
Do more with less — minimizing downtime for production workpiece measurements.
May 30, 2022
Patrick Nugent
Similar to an “All-In-One” printer/scanner/copier in a home office, a new class of production line quality machines is emerging that is designed to serve multiple functions without sacrificing quality. Using multi-sensor technology, the machine can obtain extremely accurate optical and tactile measurements for rotationally symmetrical workpieces in one setup. This multifunctional capability enables extreme flexibility in workpiece size and significantly increases productivity in the manufacturing environment.


Automated Machine Vision Systems from Augurai 


augurai team in collaboration with i6 Techlabs successfully built and deployed a challenging 360 inspection system of a cylindrical component using a single camera and state-of-the-art computer vision algorithms. 360 degree view was achieved with a single camera and without rotating the component. This was for a leading automotive component manufacturer for a POKA YOKE vision system in their their assembly line. 



HOW CAN AUTOMOTIVE PART MANUFACTURERS IMPROVE PRODUCTIVITY, PERFORM MORE INSPECTIONS FASTER AND WITH MORE INFORMATION
Solution: Portable 3D Scanning Technology
Automation is the solution to increasing productivity and aligning quality control with the production pace of the automotive industry. To do so, a robotic cell for automated quality control, such as CUBE-R, is the preferred solution.

How Does a Steel Mill Catch a Defect Rolled into the Hot Strip?
By Chris Burnett
04.26.2022

Digital Transformation in Metrology: Building a Metrological Service Ecosystem
7 Jan 2022
Two hour video presentation
_____________________




https://www.youtube.com/watch?v=wprpSYs7WYg
_____________________

New Books on Metrology


Published by De Gruyter 2022
Optical Metrology for Precision Engineering
Wei Gao and Yuki Shimizu
https://doi.org/10.1515/9783110542363

Recent Advances in Metrology
Select Proceedings of AdMeT 2021

Metrology for 5G and Emerging Wireless Technologies
Edited by Tian Hong Loh

Manufacturer Reduces First Article Inspection Time by 98%.


The project is a changeover from machining a 12-cylinder block to a 16-cylinder block. It was necessary for the first blocks produced to have full-machined audits before the production of additional blocks was initiated. In the past, this process involved removing the block from the machine and transporting it to an inspection facility. The process of  inspection can take up to a shift to complete and in this setup has to be recalibrated to accommodate the new block.

This is where the FARO Gage delivered unprecedented performance, speed and accuracy as it was able to determine if the 16-cylinder block machine settings had been correctly adjusted from those required for the 12-cylinder block.
https://www.faro.com/en/Resource-Library/Case-Study/manufacturer-reduces-first-article-inspection-time-by-98


Improvement of Tire Inspection Operations


Tire Component Inspection
Ensuring the quality of each component in the tire manufacturing process is critical to the performance and safety of each tire produced. Traditionally tire component inspection has been a manual process relying on operators to make the determination if the component meets quality standards which can be time consuming and highly variable.

In our continued efforts to provide innovative solutions Bartell has created a full line of bead inspection systems. From mechanical measurement to advanced non-contact imaging our technologies provide the most accurate measurements available and include capabilities such as networking and data storage to provide easy statistical quality analysis and documentation.

Inspection Systems for the Tire Industry - Micro-Epsilon

Tire Manufacture
Inspection Process
Tires are checked to find cracks, distortions, etc. in the inspection process.

Tires are inspected by devices to measure balance, uniformity, etc. Only tires that pass inspection will be shipped out.



Tire Inspection Goes High-speed 3D
A typical 3D vision system uses laser triangulation to capture images by projecting a laser line across the surface of each target object while a high-speed camera captures an image of the laser line as an elevation profile.


Automate Tire Manufacturing Processes and Ensure Quality with High-speed 3D Vision
August 2, 2016

Improve inspection process in tire manufacturing


2022

ABB's  3D Quality Inspection System 

ABB's  3D Quality Inspection system simplifies the measuring on manufactured products. Based on structured light and photogrammetry, 3D Quality Inspection is capable of measuring  faults that are less than half the width of a human hair at a pace that is dramatically faster than traditional measuring inspection tools. 3DQI not only offers quick and accurate quality checks, but also reduces expensive rework and scrappage. 

https://new.abb.com/products/robotics/a-z-index



#measuringhero | Episode 81: The way we inspect in the future?

ZEISS Industrial Metrology, 10 Feb 2022

https://www.youtube.com/watch?v=jxIdz28-u24


Camshaft Ball Retainer Assembly & Inspection Station | +Vantage | Metrology & Assembly Solutions

Vantage Corporation, 8 Feb 2022

https://www.youtube.com/watch?v=zPjYkzVWLvE



Multigauge for Shaft Inspection I Automation I Metrology Equipment

Metrology Equipment Pvt Ltd, 3 Nov 2021

https://www.youtube.com/watch?v=TDy1c_sBJ8k

Smart Machining - Smart Metrology

by Ray Karadayi, Applied Automation Technologies Inc.

February 15, 2022

Applied Automation Technologies (AAT3D.com), is an R&D-oriented metrology software company with more than 30 years of success in developing software that improves manufacturing quality. Our flagship product is CAPPSNC, (Computer-Aided Part-Programming System), an advanced measurement software system that enables something that decades ago would have sounded like a pipe dream: It allows CNC machine tools to perform part measurements like a CMM.

https://www.automationalley.com/articles/heres-how-smart-machining-is-improving-metrology



How to Measure Metal Coating Thickness Using Handheld X-ray Fluorescence Analyzers
Handheld XRF is an indispensable tool in quality assurance that provides multiple benefits.


Dat4zero  - The Future of Zero-Defect Manufacturing

OGP UK’s world-leading multi-sensor metrology solutions.

The OGP CNC 300 machine has  advanced multi-sensor metrology capabilities, utilising a high-quality auto-calibrating camera and supporting a combination of touch probes, micro probes and laser scanners.

ZeroTouch non-contact metrology platform
A non-contact 3D brake inspection system that measures complex geometries and performs defect detection.

The ZeroTouch® brake inspection system is a non-contact brake inspection system that generates a 3D point cloud, providing manufacturers with real-time metrology and inspection data to optimize production processes, detect defects, and improve ROI.



SMT Inspection Systems


October 2021
Improve Productivity with Poka Yoke Inspection.
RNA Carpet Gap Hider Poka Yoke Station – RNA have designed and built a bespoke workstation, applying Poka-Yoke (also called mistake proofing) requirements to prevent the human errors that result in product defects.

Bibliography - Zero-Defect Manufacturing


Arsuaga Berrueta, M. et al., 2012, ‘Instrumentation and control methodology for zero defect manufacturing in boring operations’, 
in 23rd DAAAM International Symposium on Intelligent Manufacturing and Automation 2012, pp. 385–388. 

Beckert, E., et al., 2020. Multi-sensor and closed-loop control of component and assembly processes for zero-defect manufacturing of photonics. 
In: He, S., Vivien, L. (Eds.), Smart Photonic and Optoelectronic Integrated Circuits XXII. SPIE, pp. 12. 
https://doi.org/10.1117/12.2542060

Chen, M., Lyu, J., 2011. Enhancement of measurement capability for precision manufacturing processes using an attribute gauge system. 
Proc. Inst. Mech. Eng., Part 
B: J. Eng. Manuf. 225 (10), 1912–1924. https://doi.org/10.1177/0954405410396153

Liang, C., Li, Y., Luo, J., 2018. ‘Smart measurement systems for Zero-Defect 
Manufacturing’, 
in. Proc. - IEEE 16th Int. Conf. Ind. Inform., INDIN 2018, 834–839. 
https://doi.org/10.1109/INDIN.2018.8472016

Colledani, M., Coupek, D., Verl, A., Aichele, J., Yemane, A., 2014a. Design and evaluation 
of in-line product repair strategies for defect reduction in the production of 
electric drives. 
Procedia CIRP 21, 159–164. https://doi.org/10.1016/j.procir.2014.03.186 

Colledani, M., Tolio, T., Fischer, A., Iung, B., Lanza, G., Schmitt, R., Váncza, J., 2014b. 
Design and management of manufacturing systems for production quality. 
CIRP Ann. 63 (2), 773–796. (Available at). 〈https://www.sciencedirect.com/science/ 
article/pii/S000785061400184X〉. 

Colledani, M., Coupek, D., Verl, A., Aichele, J., Yemane, A., 2018. A cyber-physical 
system for quality-oriented assembly of automotive electric motors. 
CIRP J. Manuf. Sci. Technol. 20, 12–22. https://doi.org/10.1016/j.cirpj.2017.09.001

Dimla, E., 2018. Development of an innovative tool wear monitoring system for zero-defect manufacturing. 
Int. J. Mech. Eng. Robot. Res. 7 (3), 305–312. https://doi.org/ 
10.18178/ijmerr.7.3.305-312

Eger, F., Coupek, D., Caputo, D., Colledani, M., Penalva, M., Ortiz, J.A., Freiberger, H., 
Kollegger, G., 2018. Zero Defect Manufacturing Strategies for Reduction of Scrap 
and Inspection Effort in Multi-stage Production Systems. 
Procedia CIRP 67, 368–373. https://doi.org/10.1016/j.procir.2017.12.228

Eger, F., Reiff, C., Tempel, P., Magnanini, M.C., Caputo, D., Lechler, A., Verl, A., 2020. Reaching zero-defect manufacturing by compensation of dimensional deviations in the manufacturing of rotating hollow parts. 
Procedia Manuf. 51, 388–393. 
https://doi.org/10.1016/j.promfg.2020.10.055 

Eldessouky, H.M., Flynn, J.M., Newman, S.T., 2019. On-machine error compensation for 
right first time manufacture. 
Procedia Manuf. 38, 1362–1371. https://doi.org/10. 
1016/j.promfg.2020.01.152 

Escobar, C., Arinez, J., Morales-Menendez, R., 2020. Process-Monitoring-for-Quality-A 
Step Forward in the Zero Defects Vision. 2020-April(April). SAE Tech. Pap. https:// 
doi.org/10.4271/2020-01-1302 
Ferretti, S., Caputo, D., Penza, M., D’Addona, D.M., 2013. Monitoring systems for zero 
defect manufacturing. Procedia CIRP 12, 258–263. https://doi.org/10.1016/j.procir. 
2013.09.045

Krammer, O., Varga, B., Dušek, K., 2017. New method for determining correction 
factors for pin-in-paste solder volumes. Solder. Surf. Mt. Technol. 29 (1), 2–9. 
https://doi.org/10.1108/SSMT-11-2016-0032 

Chan, H.L., Tse, A.M., Chim, A.M., Wong, V.W., Choi, P.C., Yu, J., Zhang, M., Sung, J.J., 
2015. Laser beam welding quality monitoring system based in high-speed (10 
kHz) uncooled MWIR imaging sensors. Proc. SPIE - Int. Soc. Opt. Eng. 23, 783–789. 
https://doi.org/10.1117/12.2176964

Lindström, J., Lejon, E., Kyösti, P., Mecella, M., Heutelbeck, D., Hemmje, M., Sjödahl, M., 
Birk, W., Gunnarsson, B., 2019. Towards intelligent and sustainable production 
systems with a zero-defect manufacturing approach in an Industry4.0 context. 
Procedia CIRP 81, 880–885. https://doi.org/10.1016/j.procir.2019.03.218 

Magnanini, M.C., Eger, F., Reiff, C., Colledani, M., Verl, A., 2019. A control model for 
downstream compensation strategy in multi-stage manufacturing systems of 
complex parts. IFAC-Pap. 52, 1473–1478. https://doi.org/10.1016/j.ifacol.2019.11. 
407 

Magnanini, M.C., Colledani, M., Caputo, D., 2020. Reference architecture for the industrial implementation of zero-defect manufacturing strategies. Procedia CIRP 
93, 646–651. https://doi.org/10.1016/j.procir.2020.05.154

Mahmud, K.S., et al., 2015. Development of a quality check station in a pharmaceutical 
industry to achieve zero defect production using PDCA cycle. ARPN J. Eng. Appl. 
Sci. 10 (23), 17421–17426. 

MANUFUTURE-EU, 2013, ZDM Paradigm — Manufuture Europe. Available at: 〈http:// 
www.zdmanufuture.org/zdm-paradigm〉  

Montinaro, N., Cerniglia, D., Pitarresi, G., 2018. Defect detection in additively manufactured titanium prosthesis by flying laser scanning thermography. Procedia 
Struct. Integr. 12, 165–172. https://doi.org/10.1016/j.prostr.2018.11.098 

Mourtzis, D., Angelopoulos, J., Panopoulos, N., 2021. Equipment design optimization 
based on digital twin under the framework of zero-defect manufacturing. 
Procedia Comput. Sci. 180, 525–533. https://doi.org/10.1016/j.procs.2021.01.271 

Myklebust, O., 2013. Zero defect manufacturing: a product and plant oriented lifecycle 
approach. Procedia CIRP 12, 246–251. https://doi.org/10.1016/j.procir.2013.09.043 

Nazarenko, A.A., Sarraipa, J., Camarinha-Matos, L.M., Grunewald, C., Dorchain, M., 
Jardim-Goncalves, R., 2021. Analysis of relevant standards for industrial systems 
to support zero defects manufacturing process. J. Ind. Inf. Integr. 23, 23. https:// 
doi.org/10.1016/j.jii.2021.100214

Pombo, I., Godino, L., Sánchez, J.A., Lizarralde, R., 2020. Expectations and limitations of 
cyber-physical systems (CPS) for advanced manufacturing: A view from the 
grinding industry. Future Internet 12 (9), 159. https://doi.org/10.3390/FI12090159 

Powell, D.J., Eleftheriadis, R.J., Myklebust, O., 2021. Digitally enhanced quality management for Zero-Defect Manufacturing. Procedia CIRP 104, 1351–1354 
(Forthcomin).

Psarommatis, F., May, G., Dreyfus, P.A., Kiritsis, D., 2020. Zero defect manufacturing: 
state-of-the-art review, shortcomings and future directions in research. Int. J. 
Prod. Res. 58 (1), 1–17. https://doi.org/10.1080/00207543.2019.1605228 

Psarommatis, F., 2021. A generic methodology and a digital twin for zero defect 
manufacturing (ZDM) performance mapping towards design for ZDM. J. Manuf. 
Syst. 59, 507–521. https://doi.org/10.1016/j.jmsy.2021.03.021 

Psarommatis, F., Gharaei, A., Kiritsis, D., 2020. Identification of the critical reaction 
times for re-scheduling flexible job shops for different types of unexpected 
events. Procedia CIRP 93, 903–908. https://doi.org/10.1016/j.procir.2020.03.038

Psarommatis, F., Vuichard, M., Kiritsis, D., 2020. Improved heuristics algorithms for rescheduling flexible job shops in the era of zero defect manufacturing. Procedia 
Manuf. 51, 1485–1490. https://doi.org/10.1016/j.promfg.2020.10.206 

Raabe, H., Myklebust, O., Eleftheriadis, R., 2017. Vision based quality control and 
maintenance in high volume production by use of zero defect strategies.’. 
International Workshop of Advanced Manufacturing and Automation. Springer, 
Singapore, pp. 405–412. 

Schimanski, H., et al., 2016. Investigation of the influence of electrochemical migration 
(ECM) on the reliability of electronic assemblies after rework using lead-free 
solders and No-Clean flux mixtures. Eur. Corros. Congr., EUROCORR 2016, 
300–305. 

Schmid, G. and Hanitzsch, T., 2011, ‘Managing data for a zero defect production: The 
contribution of manufacturing automation to a corporate strategy’, in ASMC 
(Advanced Semiconductor Manufacturing Conference) Proceedings. doi: 10.1109/ 
ASMC.2011.5898216. 

Shiokawa, H., Ishii, N., 2019. A method of collaborative inspection planning by integrating a production planning system. Procedia Manuf. 39, 727–736. https://doi. 
org/10.1016/j.promfg.2020.01.443

Chan, H.L., Tse, A.M., Chim, A.M., Wong, V.W., Choi, P.C., Yu, J., Zhang, M., Sung, J.J., 
2017. In-line height profiling metrology sensor for zero defect production control. 
Proc. SPIE - Int. Soc. Opt. Eng. 23, 783–789. https://doi.org/10.1117/12.2270711 

Steringer, R., Zörrer, H., Zambal, S., Eitzinger, C., 2019. Using discrete event simulation 
in multiple system life cycles to support zero-defect composite manufacturing in 
aerospace industry. IFAC-Pap. 52, 1467–1472. https://doi.org/10.1016/j.ifacol.2019. 
11.406 

Tosello, G. et al., 2019, Micro product and process fingerprints for zero-defect netshape micromanufacturing’, in European Society for Precision Engineering and 
Nanotechnology, Conference Proceedings - 19th International Conference and 
Exhibition, EUSPEN 2019, pp. 98–99.

Vu, T. et al., 2011, ‘Soldering process improvement of critical SMT connectors and for 
the retention of Press-fit SFP Cages’, in IPC APEX EXPO Technical Conference 2011, 
pp. 1325–1362.

Weng, C. and Saeger, T., 2013, Combining vision inspection and bare die packaging for 
high volume manufacturing’, in 2013 International Conference on Compound 
Semiconductor Manufacturing Technology, CS MANTECH 2013, pp. 369–372. 

Yeh, C.-H., Chen, J.E., 2019. Repeated Testing Applications for Improving the IC Test 
Quality to Achieve Zero Defect Product Requirements. J. Electron. Test.: Theory 
Appl. (JETTA) 35 (4), 459–472. https://doi.org/10.1007/s10836-019-05812-0 

Yeh, C.-H. and Chen, J.E., 2020, The Decision Mechanism Uses the Multiple-Tests 
Scheme to Improve Test Yield in IC Testing’, in Proceedings - 2020 IEEE 
International Test Conference in Asia, ITC-Asia 2020, pp. 88–93. doi: 10.1109/ITCAsia51099.2020.00027.

Zheng, T., Ardolino, M., Bacchetti, A., Perona, M., 2021. The applications of Industry 4.0 
technologies in manufacturing context: a systematic literature review. Int. J. Prod. 
Res. 59 (6), 1922–1954. https://doi.org/10.1080/00207543.2020.1824085 

Zoesch, A., Wiener, T., Kuhl, M., 2015. ‘Zero defect manufacturing: Detection of cracks 
and thinning of material during deep drawing processes. Procedia CIRP 33, 
179–184. https://doi.org/10.1016/j.procir.2015.06.033

Advancing zero defect manufacturing: A state-of-the-art perspective and future research directions
DarylPowell,   Maria Chiara Magnanini,  Marcello Colledani, Odd Myklebust 
Computers in Industry
Volume 136, April 2022, 103596

2021

NEW PRODUCTS
70% Faster In-Process Measurement
Nov. 18, 2021
For precision grinding, an automatic OD, profile measurement and compensating system measures and compensates tools to maintain tight tolerances (0.002 mm) in unmanned production.

For precision grinding, ANCA recently launched LaserUltra, an updated version of its in-process measurement technology LaserPlus, which gives customers the confidence to execute unmanned machining.

Process Precision And Metrology
Unit Manufacturing Processes: Issues and Opportunities in Research (1995)
Chapter: 13 Process Precision and Metrology

LUPHOScan 850 HD – The world’s most versatile, non-contact 3D form measurement platform for advanced large diameter optical surfaces up to Ø850 mm
The LUPHOScan 850 HD is designed to perform ultra-precision non-contact 3D surface form measurement of rotationally symmetric surfaces (optics) such as aspheric lenses, spheres, flats and slight freeform. Key benefits of the profiler/equipment include fast measurement speeds and high flexibility with regard to uncommon surface shapes (e.g. flat apexes or profiles with points of inflection).


Skoda Auto - Modernisation and Improvement of Coordinate Measuring Machines (CMMs)
Case Study 132



S. Withers, J. A. Garza-Reyes, V. Kumar, and L. Rocha-Lona, “A Case Study Improvement of a Testing Process by Combining Lean Management, Industrial Engineering and Automation Methods”, Int. j. eng. technol. innov., vol. 3, no. 3, pp. 134-143, Jul. 2013.

Customized Food Inspection/Conveying Systems
https://www.designnews.com/industry/busting-myths-about-customized-food-inspectionconveying-systems

Digital measuring heads for different workpiece sizes and profiles
Using digital measuring heads, you can determine smooth or discontinuous outside diameters of your workpieces with maximum precision and without interference.


The new measuring machine from CNC-Technik Heil GmbH is located in the middle of production—exactly what it was developed for. The SF 87 CNC coordinate measuring machine from WENZEL needs neither its own room nor a compressed air connection due to its intelligent machine concept. At the same time, it offers a high measuring volume and efficient measuring technology. 
https://www.equipment-news.com/precise-measurement-technology-directly-on-the-shop-floor/

The use of LVDTs in measuring bicycle components
https://metrologicallyspeaking.com/the-use-of-lvdts-in-measuring-bicycle-components/

Displacement Sensor and Gauge Probe Network | Orbit®
https://www.solartronmetrology.com/products/orbit-digital-measurement-network/orbit-digital-measurement-network

Displacement Sensors and Gauging Probes | Orbit®
Displacement Sensor and Gauge Probe Network | Orbit®
Standard Digital Displacement Sensors | Gauge Probes | Spring, Pneumatic, Jet , Vacuum actuation
Digital Displacement Sensors | Low Tip Force | Gauge Probes | Spring, Pneumatic, Jet, Vacuum Actuation
Digital Displacement Sensors | Compact Gauge Probes
Digital Displacement Sensors_Rugged | Gauge Probes
Digital Displacement Transducers (Block Gauges/Flexures/Mini Probes/Lever Probes/Linear Encoders) | Gauge Transducers
Linear Position Sensor Non Contact | Displacement Sensor
Digital Displacement Sensor Modules and Gauging Products | Orbit®
Digital Probes with In Line Connectors
Orbit Power Supplies and Accessories



Renishah - CMM Fixtures




Global Industrial Metrology Market (2021 to 2026) - Rise in Demand for Industry 4.0 Presents Opportunities

March  2021,  Research and Markets

The "Global Industrial Metrology Market with COVID-19 Impact Analysis by Offering, Equipment, Application (Quality & Inspection, Reverse Engineering, Mapping & Modelling), End-user Industry, and Geography - Forecast to 2026" report has been released by  ResearchAndMarkets.com. 


The global industrial metrology market is expected to grow from USD 9.8 billion in 2021 to USD 13.2 billion by 2026; it is expected to grow at a CAGR of 6.2% during the forecast period.

The market has been witnessing significant growth over the past years, mainly owing to the rising demand for big data analytics, and increasing demand for automobiles in emerging economies. Increasing adoption of cloud services to integrate metrological data and rise in demand for industry 4.0 are also expected to considerably boost the industrial metrology market in the coming years.


In terms of market size, the hardware segment is expected to dominate the industrial metrology market

The hardware segment is expected to dominate the industrial metrology market during the forecast period and is likely to witness significant growth in the said market from 2021 to 2026.

The scope of the hardware segment of the industrial metrology market includes coordinate measuring machine (CMM), optical digitizers and scanners (ODS), measuring instruments, X-ray & computed tomography, automated optical inspection systems, form measurement equipment, and 2D equipment. Companies offering hardware in the industrial metrology market are continuously working on updating their product portfolio. For instance, in recent years, FARO Technologies (US) have done various developments in its industrial metrology products, including portable measuring arms.

Industrial metrology market for CMM to register highest CAGR from 2021 to 2026

The CMM segment accounted for the largest share of the industrial metrology market and is expected to follow the trend during the forecast period. The rising need for precision dimensional analysis and validation of geometric accuracy in the manufacturing, automotive, and aerospace & defense industries is the factor responsible for the largest share of the CMM segment. The precision and accuracy of the CMM measurements are very high. Flexibility, reduced setup time, higher accuracy, and increased productivity are the major advantages of CMMs over conventional gaging.

High adoption of industrial metrology products in quality control & inspection application drives market growth

Quality control is an integral part of the production processes as it helps in the smooth functioning of the production department without incurring any extra cost. The increasing competition and need for improving safety have resulted in the high adoption of quality control and inspection systems in various industries, including automotive, aerospace & defense, and semiconductor. In these industries, maintaining and enhancing the quality of a product is of high importance. As industrial metrology equipment are the best available options in the market for quality control and inspection application, their adoption has increased at a significant rate.

APAC to witness the highest growth in the market during the forecast period

APAC is expected to witness the highest growth in the industrial metrology market during the forecast period. The industrial metrology market in APAC is expected to grow during the forecast period. Industrial metrology companies are expanding their presence in APAC. China, Japan, and India will be the major countries driving the growth of the industrial metrology market in APAC. Automobile and electronics manufacturers use industrial metrology systems during the production process for quality inspections; as the number of automobile manufacturing plants is more in APAC than other regions, the demand for industrial metrology offerings is expected to grow rapidly in this region.

7 Industrial Metrology Market, by Equipment


7.1 Introduction

7.2 Coordinate Measuring Machine (CMM)
7.2.1 Fixed CMM
7.2.1.1 Bridge CMM
7.2.1.1.1 Bridge CMM Offers Excellent Rigidity and Higher Accuracy
7.2.1.2 Gantry CMM
7.2.1.2.1 Gantry CMMs are Mainly Used for Measuring Large Objects
7.2.1.3 Horizontal Arm CMM
7.2.1.3.1 Horizontal Arm CMMs are Ideal for Measuring Large Workpieces and Parts That are Hard to Reach
7.2.1.4 Cantilever CMM
7.2.1.4.1 Cantilever CMMs are Smaller in Size and Offer High Accuracy
7.2.2 Portable CMM
7.2.2.1 Articulated Arm CMM
7.2.2.1.1 Articulated Arm CMMs Exhibit Quick and Accurate Inspection

7.3 Optical Digitizer and Scanner (ODS)
7.3.1 Laser Scanner and Structured Light Scanner
7.3.1.1 Laser Scanners Offer Fast and Non-Contact Scanning and Provide Exact Locations of Coordinates of Scanned Objects
7.3.2 Laser Tracker
7.3.2.1 Laser Trackers are Mainly Used for Measuring Large Objects by Determining Position of Optical Target

7.4 Measuring Instruments
7.4.1 Measuring Microscope
7.4.1.1 Industrial Measurement and Image Analysis are Major Applications of Measuring Microscopes
7.4.2 Profile Projector
7.4.2.1 Profile Projectors are Mainly Used to Measure Small Objects and Parts
7.4.3 Autocollimator
7.4.3.1 Autocollimators are Ideal for Measuring Small Angular Differences
7.4.4 Vision System
7.4.4.1 Vision Systems are Used for High-Resolution Measurements in Millimeter to Nanometer Range
7.4.5 Multisensor Measuring System
7.4.5.1 Multisensor Measuring Systems are Ideal for Use in Hard-To-Reach Areas Using Touch Probe

7.5 X-Ray and Computed Tomography
7.5.1 Computed Tomography Machines are Mainly Used in Industries for Detection of Flaws such as Voids and Cracks, and Analyzing Particle in Materials

7.6 Automated Optical Inspection
7.6.1 Increasing Demand for Automated Optical Inspection in Semiconductor Industry
7.7 Form Measurement Equipment
7.7.1 Form Measurement Equipment are Mainly Used for Surface Analysis and Contour Measurement
7.8 2D Equipment
7.8.1 Micrometers are Most Commonly Used 2D Equipment in Industrial Metrology Market

12 Company Profiles
12.1 Introduction

12.2 Key Players
12.2.1 Hexagon
12.2.2 Nikon
12.2.3 Faro Technologies
12.2.5 Jenoptik
12.2.6 Keyence
12.2.7 Creaform
12.2.8 KLA Corporation
12.2.9 Renishaw
12.2.10 Mitutoyo Corporation

12.3 Other Key Players
12.3.1 Precision Products
12.3.2 Carmar Accuracy
12.3.3 Baker Hughes Company
12.3.4 Cyberoptics
12.3.5 Cairnhill Metrology
12.3.6 ATT Metrology Services
12.3.7 SGS Group
12.3.8 Trimet Group
12.3.9 Automated Precision
12.3.10 Applied Materials
12.3.11 Perceptron
12.3.12 JLM Advanced Technical Services
12.3.13 Intertek Group
12.3.14 Bruker
12.3.15 Metrologic Group



For more information about this report visit https://www.researchandmarkets.com/r/iwbef


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2020 – Metrology Year in Review

December 29, 2020
We look back over 2020 and highlight Metrology News articles that featured technologies that are shaping the future of manufacturing metrology along with exclusive interviews with industry experts.


Compact Laser Line Scanner Offers Fast and Accurate CMM Inspection
December 21, 2020


Fully Automated Measurement of Complex Tubular Space Frames
November 26, 2020
Creaform has installed a second robot-controlled measuring system at Walter Automobiltechnik GmbH (WAT) in Berlin, Germany. WAT is a system supplier of complex welded assemblies such as motorcycle frames and engine mounts,  torsion struts and more for the BMW Group.

1 Dec 2020

Unique Industrial 3D metrology and inspection solution


Saccade Vision introduces the unique Industrial 3D metrology and inspection solution. By imitating certain aspects of human vision, we focus on important parts of the scene with high resolution and ignore non-important or distracting parts of the scene.

_____________

https://www.youtube.com/watch?v=2Hz0JddXqgs
_____________

Machine vision inspection system -  at a rate of hundreds of measurements per second,

Saccade Vision, an Israel based start-up venture, has developed an innovative three-dimensional machine vision solution for industrial dimensional inspection and vision guided robotics applications. The  solution includes  a unique smart hybrid 3D sensor and flexible and autonomous software. It works  the way human vision works, by selectively focusing on important information on the measured part. This  approach allows the Saccade sensor to perform highly precise and fast three-dimensional measurements and inspection with increased robustness on various materials and in different lighting conditions. The vision solution provides coordinate measuring machine (CMM) levels of precision, resolution, and robustness at a rate of hundreds of measurements per second, making it ideal for the inline process control.

https://metrology.news/game-changing-high-resolution-variable-density-scanning/

NEW PRODUCTS
MAY 21, 2020
DWFRITZ AUTOMATION has developed the ZeroTouch measuring platform that uses multiple non-contact sensor technologies to measure in three dimensions, rapidly and in real time.  Since it can perform multiple measurements in parallel using different sensors, parts and assemblies can be analyzed significantly faster than a conventional CMM.

https://www.americanmachinist.com/new-products/media-gallery/21132042/highspeed-metrology-and-inspection-dwfritz-automation

Creative Solution Cuts Inspection Times by 85%

Inspections of one of the aircraft parts during inspections as part of aircraft operations were taking too long: Seven hours is spent to thread a camera inside the part and one hour to do the actual inspection. This long setup time for inspection is causing flight delays and is making the company’s airline customers unhappy.

An administrative assistant at the organization responded to the challenge for this inspection problem posted on the organization's website. She had recently seen the Tom Cruise movie, Minority Report. She  posted the idea: “Why can’t we send a robotic spider into the part, like it was shown in the movie?”

This idea created interest in the company’s chief technology offer, and a project was initiated. A miniature camera on a remote control was set on robotic legs and the robot was walked  into the part. The prototype worked successfully. It was further refined. Now the inspections take 85 percent less time than before.
Innovation Management at Work: Real-World Use Cases
August 22, 2019 By Leyna O’Quinn
https://blog.planview.com/innovation-management-at-work-real-world-use-cases/

Engineering Metrology = NPTEL Course - Notes and Video Lectures
https://nptel.ac.in/courses/112/104/112104250/

7 Essential Metrology Tools for Modern CNC Machine Shops
Posted by Nik Seyferth on 2017 Nov 16
https://blog.eaglegroupmanufacturers.com/precision-machined-parts-measuring-tools-every-cnc-shop-should-have

The future of metrology
https://www.mtwmag.com/the-future-of-metrology/

Thoroughly Modern Metrology
Thanks to a host of ease-of-use and accuracy improvements, a new generation of 3D scanners and portable CMMs are improving productivity and reducing costs.
By Beth Stackpole
January 1, 2013
https://www.digitalengineering247.com/article/thoroughly-modern-metrology


Updated on 3.5.2022, 24 Dec 2020  1 Dec 2020, 5 August 2020
First published on 26 June 2020
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Sunday, December 3, 2023

Industrial Engineering Guidelines for Process Designers

Industrial Engineering is Cost Reduction through Productivity Improvement.

Productivity improvement is getting more output from the same resources. Materials, machines and men are considered as the three important resources. Product design, facilities design and process design influence use of resources. The contribution of industrial engineers at design stage of products, facilities and processes can be in the form of guidelines provided to designers.


Process Industrial Engineering FREE ONLINE Course & Notes

https://nraoiekc.blogspot.com/2020/06/process-industrial-engineering-free.html








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Industrial Engineering Guidelines for Product Designers

2023 BEST E-Book on #IndustrialEngineering. 

INTRODUCTION TO MODERN INDUSTRIAL ENGINEERING.PRODUCT INDUSTRIAL ENGINEERING - FACILITIES INDUSTRIAL ENGINEERING - PROCESS INDUSTRIAL ENGINEERING.  Free Download.

https://academia.edu/103626052/INTRODUCTION_TO_MODERN_INDUSTRIAL_ENGINEERING_Version_3_0 


Industrial Engineering is Cost Reduction through Productivity Improvement.

Productivity improvement is getting more output from the same resources. Materials, machines and men are considered as the three important resources. Product design, facilities design and process design influence use of resources. The contribution of industrial engineers at design stage of products, facilities and processes can be in the form of guidelines provided to designers.

The guidelines needs updates frequently.

DFMA Guidelines for Product Designers

PRODUCT INDUSTRIAL ENGINEERING. AREA of  MODERN INDUSTRIAL ENGINEERING.

https://nraoiekc.blogspot.com/2012/09/product-design-industrial-engineering.html






Related materials

https://www.cadcrowd.com/blog/product-development-guide-industrial-design-company/

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Design for Automatic Assembly

 

Doctoral Thesis

Stephan Eskilander

https://kth.diva-portal.org/smash/get/diva2:8891/FULLTEXT01.pdf



https://aapcb.com/new-blog/design-guidelines-for-effective-automated-pcb-assembly/


https://www.rs-online.com/designspark/the-complete-guide-to-designing-an-automatic-assembly-line


https://pdf.sciencedirectassets.com/280203/1-s2.0-S1877050915X00032/1-s2.0-S1877050915002884/main.pdf


https://link.springer.com/chapter/10.1007/978-1-4613-2541-3_37


https://www.launchpad.build/knowledge-center/how-to-design-for-automated-manufacturing-systems


https://www.ipa.fraunhofer.de/content/dam/ipa/en/documents/Expertises/Fabrikplanung-und-Produktionsmanagement/PB_100_152e_Design%20for%20Automation_Web_offen.pdf


https://publications.lib.chalmers.se/records/fulltext/218764/218764.pdf


https://www.brightmachines.com/viewpoints/design-for-automated-product-assembly/


https://www.linkedin.com/pulse/design-automated-assembly-dfaa-paul-choate/


https://www.ipa.fraunhofer.de/content/dam/ipa/en/documents/Expertises/Fabrikplanung-und-Produktionsmanagement/PB_100_152e_Design%20for%20Automation_Web_offen.pdf



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