World Library  
Flag as Inappropriate
Email this Article

SRI International

SRI International
nonprofit scientific research institute
Founded Menlo Park, California (1946 (1946))
Founder Trustees of Stanford University
Headquarters 333 Ravenswood Avenue
Menlo Park, California, United States
Area served
Key people
William A. Jeffrey
(President & CEO)
Manish Kothari
(President, SRI Ventures)
Revenue US$540 million (in 2014)[1]
Number of employees
2100 (as of February 2015)[1]
Website .com.sriwww

SRI International (SRI) is an American nonprofit research institute headquartered in Menlo Park, California. The trustees of Stanford University established SRI in 1946 as a center of innovation to support economic development in the region.

The organization was founded as the Stanford Research Institute. SRI formally separated from Stanford University in 1970 and became known as SRI International in 1977. SRI describes its mission as creating world-changing solutions to make people safer, healthier, and more productive.[1] It performs client-sponsored research and development for government agencies, commercial businesses, and private foundations. It also licenses its technologies,[2] forms strategic partnerships, sells products,[3] and creates spin-off companies.[4]

SRI's annual revenue in 2014 was approximately $540 million. SRI's headquarters are located near the Stanford University campus. William A. Jeffrey has served as SRI's president and CEO since September 2014.

SRI employs about 2,100 people.[1] Sarnoff Corporation, a wholly owned subsidiary of SRI since 1988, was fully integrated into SRI in January 2011.[5]

SRI's focus areas include biomedical sciences, chemistry and materials, computing, Earth and space systems, economic development, education and learning, energy and environmental technology, security and national defense, as well as sensing and devices.[6] SRI has received more than 4,000 patents and patent applications worldwide.[7]


  • History 1
    • Foundation 1.1
    • Early history 1.2
    • Rapid expansion 1.3
    • Split and diversification 1.4
    • Early 21st century 1.5
  • Description 2
    • Employees and financials 2.1
    • Facilities 2.2
    • Organization 2.3
  • Staff members and alumni 3
  • Spin-off companies 4
  • References 5
    • Notes 5.1
    • Works cited 5.2
  • Further reading 6
    • SRI history 6.1
    • Specific topics 6.2
  • External links 7



Entrance to SRI International's headquarters in Menlo Park

In the 1920s, Stanford University professor Robert E. Swain proposed creating a research institute in the Western United States. Herbert Hoover, then a trustee of Stanford University, was also an early proponent of an institute, but became less involved with the project after he was elected president of the United States. The development of the institute was delayed by the Great Depression in the 1930s and World War II in the 1940s,[8] with three separate attempts leading to its formation in 1946.

In August 1945, Maurice Nelles, Morlan A. Visel, and Ernest L. Black of Lockheed made the first attempt to create the institute with the formation of the "Pacific Research Foundation" in Los Angeles.[9] A second attempt was made by Henry T. Heald, then president of the Illinois Institute of Technology. In 1945, Heald wrote a report recommending a research institute on the West Coast and a close association with Stanford University with an initial grant of $500,000 ($16,225,000 in 2013).[10][11] A third attempt was made by Fred Terman, Stanford University's dean of engineering. Terman's proposal followed Heald's, but focused on faculty and student research more than contract research.[10]


  • SRI International website

External links

Specific topics

SRI history

Further reading

Works cited

  1. ^ a b c d e f g
  2. ^
  3. ^
  4. ^ a b
  5. ^
  6. ^
  7. ^ a b
  8. ^ Nielson, p. 1-1
  9. ^ Nielson, p. B-1
  10. ^ a b c Nielson, p. B-2
  11. ^ United States nominal Gross Domestic Product per capita figures follow the Measuring Worth series supplied in These figures follow the figures as of 2013.
  12. ^ a b c Nielson, p. B-3
  13. ^ Nielson, p. B-4
  14. ^ Gibson, SRI: The Founding Years, pp. 111-112
  15. ^ a b
  16. ^ a b c Gibson, SRI: The Founding Years, pp. 98-99
  17. ^ Gibson, SRI: The Founding Years, p. 108
  18. ^
  19. ^ a b c Nielson, pp. 9-18 - 9-21
  20. ^
  21. ^ a b Nielson, pp. 14-17 - 14-20
  22. ^ a b
  23. ^
  24. ^
  25. ^ McLaughlin, p. 39
  26. ^ a b c McLaughlin, p. 40
  27. ^ a b Nielson, pp. 6-1 - 6-3
  28. ^
  29. ^ Nielson, p. 2-8
  30. ^ Nielson, p. 2-1
  31. ^
  32. ^
  33. ^
  34. ^
  35. ^
  36. ^ DARPA, pp. 76-77
  37. ^ McLaughlin, p. 37
  38. ^
  39. ^
  40. ^ a b
  41. ^ Movie
  42. ^
  43. ^
  44. ^ DARPA, pp. 79-83
  45. ^
  46. ^
  47. ^
  48. ^
  49. ^
  50. ^
  51. ^
  52. ^
  53. ^
  54. ^ McLaughlin, p. 38
  55. ^
  56. ^
  57. ^
  58. ^ Also published in
  59. ^
  60. ^ ,
  61. ^
  62. ^
  63. ^
  64. ^ Nielson, pp. 11-7 - 11-10
  65. ^ a b
  66. ^
  67. ^
  68. ^
  69. ^
  70. ^
  71. ^
  72. ^
  73. ^
  74. ^
  75. ^
  76. ^
  77. ^
  78. ^
  79. ^
  80. ^ DARPA, p. 99
  81. ^ a b
  82. ^
  83. ^
  84. ^
  85. ^ US 3703176, Arthur Vassiliadis & Norman A. Peppers, "Slit Lamp Photocoagulator", issued Nov 2, 1972, assigned to SRI International and Stanford University 
  86. ^ Nielson, pp. 10-3 - 10-5
  87. ^ Nielson, p. 11-1
  88. ^
  89. ^
  90. ^
  91. ^
  92. ^
  93. ^
  94. ^
  95. ^
  96. ^
  97. ^
  98. ^
  99. ^
  100. ^
  101. ^
  102. ^
  103. ^
  104. ^
  105. ^
  106. ^
  107. ^
  108. ^
  109. ^ a b
  110. ^ a b
  111. ^
  112. ^
  113. ^
  114. ^
  115. ^
  116. ^
  117. ^
  118. ^
  119. ^
  120. ^
  121. ^
  122. ^
  123. ^
  124. ^
  125. ^
  126. ^
  127. ^
  128. ^
  129. ^
  130. ^
  131. ^
  132. ^
  133. ^ David Maynard at MobyGames
  134. ^ a b
  135. ^
  136. ^
  137. ^ a b
  138. ^
  139. ^
  140. ^
  141. ^ McLaughlin, p. 100
  142. ^
  143. ^
  144. ^
  145. ^
  146. ^
  147. ^
  148. ^
  149. ^
  150. ^
  151. ^ a b c d e Nielson, p. F1-F4
  152. ^
  153. ^



Research in computing and computer science-related areas led to the development of many companies, including Symantec, the Australian Artificial Intelligence Institute, E-Trade, and Verbatim Corporation. Wireless technologies spawned venture capital firm enVia Partners, Firetide and Vocera Communications.[151] Health systems research inspired Telesensory Systems.[151][153]

Former SRI staff members have also established new companies. In engineering and analysis, for example, notable companies formed by SRI alumni include Weitbrecht Communications,[152] Exponent and Raychem.[151] Companies in the area of legal, policy and business analysis include Fair Isaac Corporation, Global Business Network and Institute for the Future.[151]

Working with investment and venture capital firms, SRI and its former employees have launched more than 60 spin-off ventures[149] in a wide range of fields, including Siri (acquired by Apple), Tempo AI (acquired by, Redwood Robotics (acquired by Google), Desti (acquired by HERE), Grabit, Kasisto, Artificial Muscle, Inc. (acquired by Bayer MaterialScience), Nuance Communications, Intuitive Surgical, and Orchid Cellmark. [150][4][151]

Intuitive Surgical's robotic surgery system, the da Vinci Surgical System

Spin-off companies

Several SRI projects produced notable researchers and engineers long before computing was mainstream. Early employee Paul M. Cook founded Raychem.[145] William K. MacCurdy developed the Hydra-Cushion freight car for Southern Pacific in 1954;[27] Hewitt Crane and Jerre Noe were instrumental in the development of Electronic Recording Machine, Accounting;[40] Harrison Price helped The Walt Disney Company design Disneyland;[22] James C. Bliss developed the Optacon;[146] and Robert Weitbrecht invented the first telecommunications device for the deaf.[147][148]

The Artificial Intelligence Center has also produced a large number of notable alumni, many of whom contributed to Shakey the robot;[134] these include project manager Charles Rosen[135] as well as Nils Nilsson,[136] Bertram Raphael,[134] Richard O. Duda,[137] Peter E. Hart,[137] Richard Fikes[138] and Richard Waldinger.[139] AI researcher Gary Hendrix went on to found Symantec.[140][141] Current Yahoo! President and CEO Marissa Mayer performed a research internship in the Center in the 1990s.[142] The CALO project (and its spin-off, Siri) also produced notable names including C. Raymond Perrault and Adam Cheyer.[143][144]

Of its researchers, many notable ones were involved with the Augmentation Research Center. These include Douglas Engelbart, the developer of the modern GUI;[129] William English, the inventor of the mouse;[130] Jeff Rulifson, the primary developer of the NLS;[131] Elizabeth J. Feinler, who ran the Network Information Center;[132] and David Maynard, who would help found Electronic Arts.[133]

SRI also has a Samuel Armacost (Chairman of the Board Emeritus), Mariann Byerwalter (chairman), William A. Jeffrey, Charles A. Holloway (vice chairman), Vern Clark, Robert L. Joss, Leslie F. Kenne, Henry Kressel, David Liddle, Philip J. Quigley, Wendell Wierenga and John J. Young, Jr.[128]

SRI has had a chief executive of some form since its establishment. Prior to the split with Stanford University, the position was known as the director; after the split, it is known as the company's president and CEO. SRI has had nine so far, including William F. Talbot (1946–1947),[15] Jesse E. Hobson (1947–1955),[120] E. Finley Carter (1956–1963),[121] Charles Anderson (1968–1979),[122] William F. Miller (1979–1990),[123] James J. Tietjen (1990–1993),[124] William P. Sommers (1993–1998)[125] Curtis Carlson (1998–2014)[126] and most recently, William A. Jeffrey (2014–present).[127]

Staff members and alumni

Name Research area Reference
Advanced Technology and Systems SRI's largest organizational unit manages complex projects for government and commercial clients in areas such as chemistry, physics, and materials science; geospace studies and space and marine technology; surveillance and remote sensing; applied optics and secure circuits; and robotics, medical devices, and nanotechnology. [112]
Biosciences SRI Biosciences works with academic, commercial, foundation, and government clients and partners to bring new medicines to market through basic research, pharmaceutical discovery, pre-clinical development, and clinical translation. SRI has helped move more than 100 drugs into clinical trials. [113][114]
Education SRI Education works with government officials, private foundations, and commercial clients to provide research-based analysis and evaluation of programs to identify trends, understand outcomes, and guide public policy and practice. Focus areas include early learning, educational technology, social and emotional learning, teacher quality assessments, college and career readiness, and large-scale surveys. [115]
Global Partnerships With a goal to help businesses, universities, and government organizations across the U.S. and world maximize their success, this group researches, develops, and implements strategic programs and forges partnerships. It comprises three groups: the Center for Science, Technology, and Economic Development, the Center for Innovation Leadership, the Energy Center, and a team focused on R&D programs for international clients. [116]
Information and Computing Sciences For its government and commercial clients, this division conducts R&D activities to understand the computational principles underlying intelligence in humans and machines, and to create computer-based systems that solve problems. ICS is organized into four laboratories, one of which is SRI's Artificial Intelligence Center. The division focuses on artificial intelligence, speech recognition, natural language processing, bioinformatics, and computer security. [117]
Mission Solutions Mission Solutions performs technology and services in support U.S. government-deployed systems. The division focuses on information operations, navigation and survivability systems, and systems and signal technology. [118]
Products and Solutions This SRI division transitions R&D technology into products for its government and commercial clients. It maintains a portfolio that includes biometric identification systems, real-time video processing systems, integrated video and sensor exploitation solutions, and video test tools. [119]
[111]SRI International is organized into seven units (generally referred to as divisions) that focus on specific subject areas.


SRI is primarily based on a 63-acre (0.25 km2; 0.10 sq mi) campus located in Menlo Park, California, which is considered part of Silicon Valley. This campus encompasses 1,300,000 square feet (120,000 m2) of office and lab space.[110] In addition, SRI has a 254-acre (1.028 km2; 0.397 sq mi) campus in Princeton, New Jersey, with 600,000 square feet (56,000 m2) of research space. There are also offices in Washington, D.C., and Tokyo, Japan. In total, SRI has 2,300,000 square feet (210,000 m2) of office and laboratory space.[110]


As of February 2015, approximately 4,000 patents have been granted to SRI International and its employees.[7]

As of February 2015, SRI employs approximately 2,100 people.[1] In 2014, SRI had about $540 million in revenue.[1] In 2013, the United States Department of Defense consisted of 63% of awards by value; the remainder was composed of the National Institutes of Health (11%); businesses and industry (8%); other United States agencies (6%); the National Science Foundation (6%); the United States Department of Education (4%); and foundations (2%).[109]

Employees and financials

SRI awards by source[109]
  Department of Defense (63%)
  National Institutes of Health (11%)
  Business and industry (8%)
  US State and Local (6%)
  US National Science Foundation (6%)
  US Department of Education (4%)
  Foundations (2%)


In February 2014, SRI announced a "photonics-based testing technology called FASTcell" for the detection and characterization of rare circulating tumor cells from blood samples. The test is aimed at cancer-specific biomarkers for breast, lung, prostate, colorectal and leukemia cancers that circulate in the blood stream in minute quantities, potentially diagnosing those conditions earlier.[107][108]

For the National Science Foundation (NSF), SRI operates the advanced modular incoherent scatter radar (AMISR), a novel relocatable atmospheric research facility.[105] Other SRI-operated research facilities for the NSF include the Arecibo Observatory in Puerto Rico and the Sondrestrom Upper Atmospheric Research Facility in Greenland. In May 2011, SRI was awarded a $42 million contract to operate the Arecibo Observatory from October 1, 2011 to September 30, 2016.[106]

[104] In December 2007, SRI launched a spin-off company,

In 2006, SRI was awarded a $56.9 million contract with the National Institute of Allergy and Infectious Diseases to provide preclinical services for the development of drugs and antibodies for anti-infective treatments for avian influenza, SARS, West Nile virus and hepatitis.[96] Also in 2006, SRI selected St. Petersburg, Florida, as the site for a new marine technology research facility targeted at ocean science, the maritime industry and port security; the facility is a collaboration with the University of South Florida College of Marine Science and its Center for Ocean Technology.[97][98][99] That facility created new a method for underwater mass spectrometry, which has been used to conduct "advanced underwater chemical surveys in oil and gas exploration and production, ocean resource monitoring and protection, and water treatment and management" and was licensed to Spyglass Technologies in March 2014.[100]

A building on SRI International's campus

SRI researchers made the first observation of visible light emitted by oxygen atoms in the night-side airglow of Venus, offering new insight into the planet's atmosphere.[90][91][92] SRI education researchers conducted the first national evaluation of the growing U.S. charter schools movement. For the World Golf Foundation, SRI compiled the first-ever estimate of the overall scope of the U.S. golf industry's goods and services ($62 billion in 2000), providing a framework for monitoring the long-term growth of the industry.[93][94] In April 2000, SRI formed Atomic Tangerine, an independent consulting firm designed to bring new technologies and services to market.[95]

Early 21st century

[89] SRI performed a study in the 1990s for

In medicine and chemistry, SRI developed dry-powder drugs,[84] laser photocoagulation (a treatment for some eye maladies),[85] remote surgery (also known as telerobotic surgery), bio-agent detection using upconverting phosphor technology, the experimental anticancer drugs Tirapazamine and TAS-108, ammonium dinitramide (an environmentally benign oxidizer for safe and cost-effective disposal of hazardous materials), the electroactive polymer ("artificial muscle"), new uses for diamagnetic levitation, and the antimalarial drug Halofantrine.[26][86]

With DARPA-funded research, SRI contributed to the development of speech recognition and translation products[80][81] and was an active participant in DARPA's Global Autonomous Language Exploitation (GALE) program.[81] SRI developed DynaSpeak speech recognition technology which was used in the handheld VoxTec Phraselator, allowing U.S. soldiers overseas to communicate with local citizens in near real time.[82] SRI also created translation software for use in the IraqComm, a device which allows two-way, speech-to-speech machine translation between English and colloquial Iraqi Arabic.[83]

The IraqComm system

SRI created the Centibots in 2003, one of the first and largest teams of coordinated, autonomous mobile robots that explore, map, and survey unknown environments.[76][77][78][79]

Military-related technologies developed by SRI in the 1990s and 2000s include ground- and foliage-penetrating radar, the INCON and REDDE command and control system for the U.S. military,[74] and IGRS (integrated GPS radio system)—an advanced military personnel and vehicle tracking system. To train armored combat units during battle exercises, SRI developed the Deployable Force-on-Force Instrumented Range System (DFIRST), which uses GPS satellites, high-speed wireless communications, and digital terrain map displays.[75]

In 1986, became the 8th registered ".com" domain.[71] The Artificial Intelligence Center developed the Procedural Reasoning System (PRS) in the late 1980s and into the early 1990s. PRS launched the field of BDI-based intelligent agents.[72] In the 1990s, SRI developed a letter sorting system for the United States Postal Service and several education and economic studies.[73]

Throughout the 1980s, SRI developed Zylon,[64] stealth technologies, improvements to ultrasound imaging,[26] two-dimensional laser fluorescence imaging,[65] and order-sorted algebra. In computing and software, SRI developed a multimedia electronic mail system, a theory of non-interference in computer security, a multilevel secure (MLS) relational database system called Seaview,[65] LaTeX,[66] Open Agent Architecture (OAA), a network intrusion detection system, the Maude system, a declarative software language, and PacketHop, a peer-to-peer wireless technology to create scalable ad hoc networks.[67] SRI's research in network intrusion detection led to the patent infringement case SRI International, Inc. v. Internet Security Systems, Inc.[68] The AI center's robotics research led to Shakey's successor, Flakey the robot, which focused on fuzzy logic.[69][70]

Social scientist and consumer futurist Arnold Mitchell created the Values, Attitudes and Lifestyles (VALS) psychographic methodology in the late 1970s to explain changing U.S. values and lifestyles.[62] VALS was formally inaugurated as an SRI product in 1978 and was called "one of the ten top market research breakthroughs of the 1980s" by Advertising Age magazine.[63]

In 1972, physicists Harold E. Puthoff and Russell Targ undertook a series of investigations of psychic phenomena sponsored by the CIA, for which they coined the term remote viewing.[56][57][58] Among other activities, the project encompassed the work of consulting "consciousness researchers" including artist/writer Ingo Swann, military intelligence officer Joseph McMoneagle, and psychic/illusionist Uri Geller.[59] This ESP work continued with funding from the US intelligence community until Puthoff and Targ left SRI in the mid-1980s.[60][61] For more information, see Parapsychology research at SRI.

Aerial image of SRI's Menlo Park campus

[55][54][1] The

Split and diversification

This first true Internet transmission occurred on November 22, 1977, when SRI originated the first connection between three disparate networks. Data flowed seamlessly through the mobile Packet Radio Van between SRI in Menlo Park, California and the University of Southern California in Los Angeles via London, England, across three types of networks: packet radio, satellite, and the ARPANET.[50] In 2007, the Computer History Museum presented a 30th anniversary celebration of this demonstration, which included several participants from the 1977 event.[51] SRI would go on to run the Network Information Center under the leadership of Jake Feinler.[52]

On October 29, 1969, the world's first electronic computer network, ARPANET, was established between nodes at Leonard Kleinrock's lab at UCLA and Douglas Engelbart's lab at SRI. Interface Message Processors at both sites served as the backbone of the first Internet.[43][44] The following year, Engelbart's lab installed the first TENEX system outside of BBN where it was developed. In addition to SRI and UCLA, UCSB and the University of Utah were part of the original four network nodes. By December 5, 1969, the entire four-node network was connected. In the 1970s, SRI developed packet-switched radio (a precursor to wireless networking),[45] over-the-horizon radar,[46][47] Deafnet,[48][49] vacuum microelectronics, and software-implemented fault tolerance.

The Packet Radio Van, developed by Don Cone, was the site of the first three-way internetworked transmission.

In 1966, SRI's Artificial Intelligence Center began working on "Shakey the robot", the first mobile robot to reason about its actions.[41] Equipped with a television camera, a triangulating range finder, and bump sensors, Shakey used software for perception, world-modeling, and acting. The project ended in 1972.[42] SRI's Artificial Intelligence Center marked its 45th anniversary in 2011.

In the early 1960s, Hewitt Crane and his colleagues developed the world's first all-magnetic digital computer,[39] based upon extensions to magnetic core memories. The technology was licensed to AMP, who then used it to build specialized computers for controlling tracks in the New York City Subway and on railroad switching yards.[40]

Bill English, then chief engineer at the ARC, built the first prototype of a computer mouse from Engelbart's design in 1964.[35][36] SRI also developed inkjet printing (1961) and optical disc recording (1963).[37] Liquid crystal display (LCD) technology was developed at RCA Laboratories in the 1960s, which later became Sarnoff Corporation in 1988, a wholly owned subsidiary of SRI. Sarnoff was fully integrated into SRI in 2011.[38]

Douglas Engelbart, the founder of SRI's Augmentation Research Center (ARC), was the primary force behind the design and development of the multi-user oN-Line System (or NLS), featuring original versions of modern computer-human interface elements including bit-mapped displays, collaboration software, hypertext, and precursors to the graphical user interface such as the computer mouse.[33] As a pioneer of human-computer interaction, Engelbart is arguably SRI's most notable alumnus. He was awarded the National Medal of Technology and Innovation in 2000.[34]

The first prototype of a computer mouse, as designed by Bill English

Rapid expansion

In the 1950s, SRI worked under the direction of the Bank of America to develop ERMA (Electronic Recording Machine, Accounting) and magnetic ink character recognition (MICR). The ERMA project was led by computer scientist Jerre Noe, who was at the time SRI's assistant director of engineering.[29] As of 2011, MICR remains the industry standard in automated check processing.[30][31][32]

In 1952, the Technicolor Corporation contracted with SRI to develop a near-instantaneous, electro-optical alternative to the manual process of timing during film copying.[25] In 1959, the Academy of Motion Picture Arts and Sciences presented the Scientific and Engineering Award jointly to SRI and Technicolor for their work on the design and development of the Technicolor electronic printing timer which greatly benefited the motion picture industry.[26] In 1954, Southern Pacific asked SRI to investigate ways of reducing damage during rail freight shipments by mitigating shock to railroad box cars. This investigation led to William K. MacCurdy's development of the Hydra-Cushion technology, which remains standard today.[27][28]

In the early 1950s, Walt and Roy Disney consulted with SRI (and in particular, Harrison Price) on their proposal for Disneyland in Burbank, California.[21] SRI provided information on location, attendance patterns, and economic feasibility. SRI selected a larger site in Anaheim, prepared reports about operation, and provided on-site administrative support, and acted in an advisory role as the park expanded.[21][22][23] In 1955, SRI was commissioned to select a site and provide design suggestions for the John F. Kennedy Center for the Performing Arts.[24]

The ERMA system, which uses magnetic ink character recognition to process checks, was one of SRI's earliest developments.

The institute performed much of the early research on air pollution and the formation of ozone in the lower atmosphere.[19] SRI sponsored the First National Air Pollution Symposium in Pasadena, California, in November 1949.[19] Experts gave presentations on pollution research, exchanged ideas and techniques, and stimulated interest in the field. The event was attended by 400 scientists, business executives, and civic leaders from the U.S.[19] SRI co-sponsored subsequent events on the subject.[20]

SRI's first economic study was for the United States Air Force. In 1947, the Air Force wanted to determine the expansion potential of the U.S. aircraft industry; SRI found that it would take too long to escalate production in an emergency.[17] In 1948, SRI began research and consultation with Chevron Corporation to develop an artificial substitute for tallow and coconut oil in soap production; SRI's investigation confirmed the potential of dodecyl benzene as a suitable replacement. Later, Procter & Gamble used the substance as the basis for Tide laundry detergent.[18]

SRI's first research project investigated whether the guayule plant could be used as a source of natural rubber.[16] During World War II, rubber was imported into the U.S. and was subject to shortages and strict rationing.[16] From 1942 to 1946, the United States Department of Agriculture (USDA) supported a project to create a domestic source of natural rubber. Once the war ended, the United States Congress cut funding for the program; in response, the Office of Naval Research created a grant for the project to continue at SRI, and the USDA staff on the project worked through SRI until Congress reauthorized funding in 1947.[16]

SRI participant Paul Magill discussing the smog on Black Friday in Los Angeles at the first National Air Pollution Symposium in 1949

Early history

[15], but the pursuit of contract work remained.Armour Research Foundation, who had previously led the Jesse Hobson Talbot was replaced by [14] Research chemist


This article was sourced from Creative Commons Attribution-ShareAlike License; additional terms may apply. World Heritage Encyclopedia content is assembled from numerous content providers, Open Access Publishing, and in compliance with The Fair Access to Science and Technology Research Act (FASTR), Wikimedia Foundation, Inc., Public Library of Science, The Encyclopedia of Life, Open Book Publishers (OBP), PubMed, U.S. National Library of Medicine, National Center for Biotechnology Information, U.S. National Library of Medicine, National Institutes of Health (NIH), U.S. Department of Health & Human Services, and, which sources content from all federal, state, local, tribal, and territorial government publication portals (.gov, .mil, .edu). Funding for and content contributors is made possible from the U.S. Congress, E-Government Act of 2002.
Crowd sourced content that is contributed to World Heritage Encyclopedia is peer reviewed and edited by our editorial staff to ensure quality scholarly research articles.
By using this site, you agree to the Terms of Use and Privacy Policy. World Heritage Encyclopedia™ is a registered trademark of the World Public Library Association, a non-profit organization.

Copyright © World Library Foundation. All rights reserved. eBooks from World Library are sponsored by the World Library Foundation,
a 501c(4) Member's Support Non-Profit Organization, and is NOT affiliated with any governmental agency or department.