Difference between revisions of "IEEE New Jersey Coast Section History"

(edits)
(link video for Milestone)
(3 intermediate revisions by the same user not shown)
Line 56: Line 56:
  
 
==Celebrating Our History - IEEE Milestone Reflection of Radar off the Moon - Project DIANA==
 
==Celebrating Our History - IEEE Milestone Reflection of Radar off the Moon - Project DIANA==
 +
 +
[https://youtu.be/-405RI0-0kw Click to view IEEE NJ Coast Section Milestone DIANA Video]
 +
 
'''Celebrate Our History -- a New Jersey Coast Section IEEE Milestone 2016-02 Reflection of Radar off the Moon,''' [https://ethw.org/Project_Diana Project DIANA].  
 
'''Celebrate Our History -- a New Jersey Coast Section IEEE Milestone 2016-02 Reflection of Radar off the Moon,''' [https://ethw.org/Project_Diana Project DIANA].  
  
Line 90: Line 93:
  
 
On Saturday, 18 May 2019 at InfoAge in Wall Township, New Jersey, the site of the initial Moonbounce Experiment, the IEEE Milestone plaque was placed at a ceremony at 10:00am, including an unveiling by the Mayor of Wall, the previous president of IEEE, John Vig. Dr Gregory Wright presented. Refreshments were served.  
 
On Saturday, 18 May 2019 at InfoAge in Wall Township, New Jersey, the site of the initial Moonbounce Experiment, the IEEE Milestone plaque was placed at a ceremony at 10:00am, including an unveiling by the Mayor of Wall, the previous president of IEEE, John Vig. Dr Gregory Wright presented. Refreshments were served.  
 +
 +
[[File:IEEE NJ Coast Section History Collage.jpg|alt=IEEE NJ Coast Section History Collage of images|thumb]]
  
 
==New IEEE Milestone Reflection of Radar off the Moon Celebration in the IEEE New Jersey Coast Section==
 
==New IEEE Milestone Reflection of Radar off the Moon Celebration in the IEEE New Jersey Coast Section==
Line 184: Line 189:
  
 
LTC Dr John H. DeWitt, Jr. - [https://en.wikipedia.org/wiki/John_H._DeWitt_Jr. Wikipedia link,] [http://articles.adsabs.harvard.edu/full/1988IAPPP..31...10S Harvard link,] [https://aas.org/obituaries/john-hibbett-dewitt-jr-1906-1999 Obituary,] IEEE Member Directory 1996 Entry for John J DeWitt, Jr
 
LTC Dr John H. DeWitt, Jr. - [https://en.wikipedia.org/wiki/John_H._DeWitt_Jr. Wikipedia link,] [http://articles.adsabs.harvard.edu/full/1988IAPPP..31...10S Harvard link,] [https://aas.org/obituaries/john-hibbett-dewitt-jr-1906-1999 Obituary,] IEEE Member Directory 1996 Entry for John J DeWitt, Jr
 
 
===<u>Women's History in Engineering and Technology</u>===
 
===<u>Women's History in Engineering and Technology</u>===
 
Celebrating Our History: Inventing Your Future
 
Celebrating Our History: Inventing Your Future
Line 306: Line 310:
 
File:VictorLawrence-MikeMolnarIMG 20190312 221849 550.jpg  
 
File:VictorLawrence-MikeMolnarIMG 20190312 221849 550.jpg  
 
</gallery>
 
</gallery>
 +
 +
===<u>New IEEE Milestone Neutrodyne Inspires Humanitarian Activities - Collaboration with North Jersey and Stevens Institute of Technology Student Chapter</u>===
 +
[https://youtu.be/T0IGuBnEF6I Click for IEEE Futurecast Milestone Neutrodyne Video]
 +
 +
by Katherine Grace August, PhD
 +
 +
'''IEEE History Inspires Humanitarian Activities''' - As we have learned from a model in the chapters of IEEE History, Professor Louis A Hazeltine of Stevens Institute of Technology, and his Team who in 1922 developed the Neutrodyne Circuit, it is possible to advance technology for humanity, and to transform the world in which we live by making engineering decisions to benefit humans. The Neutrodyne circuit simplified radio tuning eliminating parasitic oscillation, that terrible squealing and unstable tuning. Because the Hazeltine Team licensed twenty manufacturers, together they were successful in changing the business model for radio. The field was previously monopolized by RCA and their Proprietary solutions for the RCA Super Heterodyne Circuit. By producing ten million Neutrodynes in about three years, Professor Hazeltine’s Team and licensees rapidly expanded the population of people who had access to radios.
 +
 +
Even people on farms and in the mountains could now own a radio. They no longer had to wait for news, to wait to hear what was happening in the towns, and cities, in the Nation’s Capital of Washington DC, across Europe and around the globe. Every person was able to hear the sound bites and make informed decisions when they voted. Even if they could not read, they could gather information and learn. People had wide access to a unifying and common language and vocabulary. Ordinary people could engage in leisure activities listening to music and cultural programming anywhere in the country. Even in the most remote places. People everywhere could actively participate in Democracy.
 +
 +
Caption: Professor Hazeltine, the Neutrodyne Circuit, Stevens Campus - Navy Building
 +
 +
Prior to the commercial development and distribution of the Neutrodyne circuit, only wealthy people with a high level of skill could own and operate radio receivers. Because of the insight and experience Professor Hazeltine had working with the Navy, he keenly recognized the humanity involved in the situation. Every person’s life is valuable. He recognized it was not only the engineering, but also the business model that created disparity – that created a gap between people who have access and those who do not.
 +
 +
Access to technology means life or death, participation in the important aspects of opportunities in our society, in the economy, in education, healthcare, or in the alternative – to experience disparity. He recognized that an expensive solution would necessarily create and attenuate a gulf between humans who can participate, and those who are left out forever because opportunity is passed along to the family, shared by the community, and then to the next generations.
 +
[[File:Professor Hazeltine's Lab Notebook, Neutrodyne Logo, Circuit.jpg|alt=Professor Hazeltine's Lab Notebook, Neutrodyne Logo, Circuit|thumb]]
 +
 +
Caption: Professor Hazeltine Notebooks, Neutrodyne Logo
 +
 +
When Professor Hazeltine embraced a low cost simplified solution, and licensed it making it widely available at a rapid pace, he was a great steward and a role model for the rest of us to use our engineering skills to address the needs of our society and to do it at a lower cost and to do it with a goal – to create a much greater impact, to reduce suffering and to improve opportunity for society.
 +
 +
And Professor Hazeltine illustrated the significance of engineering decisions in transforming opportunities for humans everywhere. Millions of people’s lives were changed and our society was transformed by the remarkable achievements of the Neutrodyne Team. They created mass communication with its vast and immeasurable benefits, and all that enables.
 +
 +
Today, we cannot imagine our world without mass communication. We admire the achievements of the Neutrodyne Team and take notice of the opportunity we have today to make a difference by advancing technology for humanity, by providing lower cost solutions that have a wider impact on society: advance technology for humanity in our community and around the globe.
 +
 +
Within three years of introducing the Neutrodyne, radio ownership grew from 10 percent to 60 percent of the population of North America ushering in Mass Communication that Democratized Politics and forever changed the way people access information, news, music and culture with lasting effects evident in our everyday lives. Even today, we can step up to the challenge and advance technology for humanity, making decisions every day to engineer with a heart. Advancing technology for humanity for the benefit of all the far reaches of the globe, and for our fellow human beings in our own communities.
 +
 +
In the IEEE NJ Coast Section, with our Humanitarian Activities, and our NJ Coast Section SIGHT Group we are very aware of and inspired by the parallels between the legacy of the Neutrodyne and the opportunities for improving technology in our environment today. We are inspired to make excellent engineering decisions for the benefit of humanity – for those with hearing loss, to heal diseases, educate, improve job safety, and to deal with other fundamental needs that must be solved in order to bridge the gap, reduce disparity, welcome humans everywhere to be full participants in society, the economy, in their own lives and in the lives of their families.
 +
 +
In our Humanitarian Activities, Hear, here! we hold as a goal to facilitate providing at least one viable low-cost solution accessible to everyone by promoting IEEE Standards to reduce the impact of proprietary solutions, just as Neutrodyne did in their day. Proprietary solutions in the case of hearing assistance keep technology solutions from helping the people who need them most – people who need to have lower cost access to technology so they can participate fully. There is a vast opportunity for technology to be helpful, since only about 10 percent of the hearing aids needed are produced. In 2020, FDA will allow hearing assistance that doesn’t require prescriptions making this an ideal time to offer new solutions. It is up to us to understand and use our skills to reduce disparities wherever we find them.
 +
 +
We set our goals high and we invite you to join. We aim to raise awareness, capture and share the Stories, be Connectors, and transform opportunities on campuses, in organizations, with company solutions, and to model and inspire others to use our engineering skills to advance technology for humanity in our community and around the globe. That is our model to meet the United Nations Sustainable Development Goals.
 +
[[File:Professor Hazeltine, Neutrodyne, Navy Building at Stevens Institute of Technology.jpg|alt=Professor Hazeltine, Neutrodyne, Stevens Campus Navy Building|thumb]]
  
 
==Interview with Professor Dr Don Heirman, 2018  [[IEEE Richard M. Emberson Award]] Winner, IEEE Life Fellow and Member of the New Jersey Coast Section -- History in Hearing Aids, Electromagnetic Compatibility, T-Coil Technologies, Mobile Phones, etc.==
 
==Interview with Professor Dr Don Heirman, 2018  [[IEEE Richard M. Emberson Award]] Winner, IEEE Life Fellow and Member of the New Jersey Coast Section -- History in Hearing Aids, Electromagnetic Compatibility, T-Coil Technologies, Mobile Phones, etc.==

Revision as of 05:59, 11 October 2019






IEEE New Jersey Coast Section History
Established date 1965/03/20
IEEE Region 1
IEEE Council Metro Sec. Act.
Geographic region New Jersey Coast
Region area
Principal cities
Home page
List of Subsections in this Section

Brief History

The New Jersey Coast Section of the IEEE was established March 20, 1965.

Below is a list of awards to members of the New Jersey Coast Section from 1965 -1984.

Centennial Awards: John G. Nordahl, Martin V. Schneider, Robert C. Eckenfelder, A. Gardner Fox, Bruce C. Miller, Vasant K. Prabhu, Luke G. Schimpf, Robert W. Wilson, Mary N. Youssef.

Celebrating Our History - IEEE Milestone Reflection of Radar off the Moon - Project DIANA

Click to view IEEE NJ Coast Section Milestone DIANA Video

Celebrate Our History -- a New Jersey Coast Section IEEE Milestone 2016-02 Reflection of Radar off the Moon, Project DIANA.

Diana, Goddess of the Moon

The 2019 Joint IEEE Princeton/Central Jersey and New Jersey Coast Section Awards Banquet was held at the Grand Ballroom, Colts Neck Inn, Colts Neck, NJ, on Friday, May 17, 2019, and began at 6 pm. The IEEE Princeton/Central Jersey Section and the IEEE New Jersey Coast Section organized this joint event to pay tribute to the new IEEE Fellows in the Sections, the IEEE Region 1 and Section Award recipients, and to celebrate the IEEE Milestone Project DIANA - Detection of Radar Signals Reflected from the Moon. The significance of this milestone is summarized by the citation: On 10 January 1946, a team of military and civilian personnel at Camp Evans, Fort Monmouth, New Jersey, USA, reflected the first radar signals off the Moon using a specially modified SCR-270/1 radar. The signals took 2.5 seconds to travel to the Moon and back to the Earth. This achievement, Project Diana, marked the beginning of radar astronomy and space communications.

Keynote Speaker Gregory Wright PhD by KG August PhD at Bell Labs Crawford Hill Holmdel New Jersey 2018.

An Introduction to the IEEE Milestone for Project DIANA was given by Dr Al Kerecman, and the Keynote Speaker was Dr Gregory Wright.

Keynote Speaker Dr Gregory Wright

Abstract: Shortly after the end of the Second World War, radio engineers from Fort Monmouth succeeded in bouncing radar signals off of the moon. In the next twenty years, radar signals would also be reflected off the planets Mars and Venus. Why would anyone want to do this and what was learned?

The answer to this question is a fascinating tale of the early space age and Cold War superpower rivalry.

The celebration focused on recognizing the achievements of our members and their contributions to the engineering profession, our community, and the IEEE Princeton/Central Jersey and New Jersey Coast Section activities. The Banquet provided a unique opportunity for companies and organizations to meet and congratulate the awardees and showcase their local presence.

Bio: Gregory Wright is a Member of Technical Staff at Nokia Bell Labs, where he works on antenna arrays and their implementation in low cost integrated circuits. Most relevant to the topic at hand, he was the last radio astronomer hired by Bell Labs. He was a co-investigator on the Antarctic Submillimeter Telescope and Remote Observatory, the first permanent radio telescope located at the South Pole. Before joining Bell Labs, he was co-founder of two start up companies.

Greg received a Ph.D. in physics from Princeton University, a master's degree in mathematics from Cambridge University and his bachelor's degree in physics from Harvard University.

On Saturday, 18 May 2019 at InfoAge in Wall Township, New Jersey, the site of the initial Moonbounce Experiment, the IEEE Milestone plaque was placed at a ceremony at 10:00am, including an unveiling by the Mayor of Wall, the previous president of IEEE, John Vig. Dr Gregory Wright presented. Refreshments were served.

IEEE NJ Coast Section History Collage of images

New IEEE Milestone Reflection of Radar off the Moon Celebration in the IEEE New Jersey Coast Section

Perhaps the most important thing IEEE can do for Members is to recognize their remarkable achievements and provide testimony and inspiration for inventing our future. Coincidentally in this same year, the world remembers and celebrated the Apollo mission to the Moon, and we celebrated his sister, Diana with our own Section IEEE Milestone for Project Diana, the first successful Earth-Moon-Earth bounce of radar which demonstrated communication beyond the ionosphere, and launched space communication. This important IEEE Milestone in History gave us the opportunity to gather together, meet with others in our Section, and remember the achievements of those who have come before us. We share herein the History of the latest IEEE Milestone Reflection of Radar off the Moon which was Celebrated 17 May 2019 at the Awards Banquet and also on 18 May 2019 at the original site of Camp Evans, now InfoAge in Wall Township, New Jersey.

It's totally worthwhile to spend the time and energy to investigate and promote IEEE Milestones in each Section. There is a substantial amount of research and documentation required in order to succeed and add an IEEE Milestone. Thank-you, Al Kerecman of the IEEE NJ Coast Section, and Rob Colburn of the IEEE History Center, and everyone who played a role in this achievement. This is no small effort. To give a glimpse behind the curtain of the significance of the newest Milestone for Project DIANA, the background materials are being included in the Section History.

On 10 January 1946, a team of military and civilian personnel at Camp Evans, Fort Monmouth, New Jersey, USA, reflected the first radar signals off the Moon using a specially modified SCR-270/1 radar. The signals took 2.5 seconds to travel to the Moon and back to the Earth. This achievement, Project Diana, marked the beginning of radar astronomy and space communications.

Excellent support documentation accompanied the application.

What is the historical significance of the work (its technological, scientific, or social importance)?

Proof of Concept

The effort resolved doubts about whether Electromagnetic Waves suitable for long-range communication and RADAR could penetrate the Earth’s Ionosphere. It was the first documented experiment in radar astronomy and in actively probing another celestial body, and it began the space age, with Site Diana, Camp Evans, Fort Monmouth, New Jersey, USA, personnel demonstrating the ability to communicate with extraterrestrial bodies beyond Earth. These results emboldened a series of ideas ranging from worldwide wireless communication, radar astronomy, artificial satellites, and rocket launched probes to the moon and planets.

Prior to the success of the experiment, wireless communication was performed using “skywave” communication up to about 400 km, where signals were reflected or refracted off the ionosphere. While this form of communication was not limited by curvature of the earth line-of-sight, it was restricted in frequency, range and data rate. Demonstrating that signals could travel from the earth to the moon and back was proof of concept for the idea of what is known as Earth-Moon-Earth (EME), or “moon-bounce” communication.

Following the success of the project, the US Navy set out to explore the implications and applications of this form of communication - the idea of a reliable, secure EME scheme. The first major milestone to this Passive Moon Relay project happened on July 24, 1954, where voice was successfully transmitted from Stump Neck, Maryland to Washington, DC. Following this success, on November 20, 1955, transmissions were sent to San Diego, California and soon after to Wahiawa, Hawaii.The system in its completed state began seeing use in 1960 and was expanded to accommodate ship-to-shore transmissions. In the later 1960s the system became obsolete due to the advent of artificial satellites in orbit to serve the same purpose.

The Diana Project involving a two-way path, concluded that one-way communication paths to and from the moon as well as other celestial bodies were achievable, and “that even without an extraordinary antenna system, an FM broadcast station on earth could be readily received on the moon.”

Radar Astronomy

Before 1946, scientists observed the universe using large passive radio telescopes that caught and recorded radio waves emanating from the universe outside the earth’s atmosphere. This technique of passive reception was part of a field known as radio astronomy. Following the success of Project Diana, scientists had access to what is known as radar astronomy. Unlike radio astronomy, this technique is an active observation by reflecting microwaves off objects and analyzing the reflected signals, in the same manner as Project Diana had done with the moon. Radar astronomy has many advantages over previous forms of observation. The ability to control and measure the source of the transmission allowed scientists to extract information that was difficult to obtain before, such as composition and relativistic data. Since 1946, this technique has been used to gather a wealth of data about the geological and dynamic properties of many of the planets, moons, and asteroids that orbit our sun. Additionally, it has been used to determine the length of the astronomical unit (AU) and the scale of the solar system itself.

Space Age

Almost more importantly than any other benefit, the success of the project became a symbol that lead to the beginning of the Space Age for the United States. Days after the success of the project, the New York Times commented that &quot;somehow ... the moon and all the heavenly bodies become more real ... more than a guide to navigators and an inspiration to poets ... tangible objects to which we can reach out.&quot; For the first time in its history, the US was able to “touch the stars” so to speak, where it could communicate with objects and potential beings well outside of its grasp up until that point. With this new found reach from a communications perspective, the US sought to extend that to a physical presence. In the early 1950s, President Dwight Eisenhower was skeptical about the possibility of human spaceflight, although he did see promise in artificial satellites for commercial and military use. However, the space stage was finally set to explore our solar system, when President John F. Kennedy set a goal of sending men to the moon by 1968.

Detect and Control Guided Missiles

Following the success of the project, the War Department talked about &quot;radio control of missiles orbiting Earth above the stratosphere.&quot; Indeed, today, earth satellites and space probes to the farthest reaches of our solar system are directed and re-positioned via this “radio control” of the probe vehicles.

Boosted US Morale

This achievement brought promise of a coming golden age of science and technology arising from the aftermath of World War II. It refocused engineers and scientists to new goals centered on benefiting humanity, and created a need for developing solid state technologies, capable of surviving space launch and environments.

What obstacles (technical, political, geographic) needed to be overcome?

LTC John H DeWitt, Jr IRE Fellow
Dewitt-IEEE-Record.jpg

Bandwidth Requirements

LTC. DeWitt, E. King Stodola, Jack Mofenson, Dr. Harold Webb, Herbert P. Kauffman and a contributing team including: Edwin Armstrong, W. S. McAfee, F. Blackwell, G. Cantor, J. Corwin, A. Davis, R. Guthrie, A. Kampinsky, H. Lisman, C.G. McMullen, W.S. Pike, J. Ruze, J. Snyder, and O.C. Woodward, had calculated that they needed a narrow bandwidth of +-20 Hz on a 111.5 MHz signal to properly conduct the experiment. This meant that, as a base requirement to success, they needed to have a very stable system. This stability requirement far exceeded the usual requirements on most radars, so the team replaced the SCR270/1 receiver by modifying E. H. Armstrong’s developed transmitting and receiving equipment that employed a single, crystal controlled source that was multiplied to provide the first three separate local oscillator frequencies needed, and which also supplied control of the transmitter oscillator. After three fixed heterodyne stages, the final heterodyne employed an independent adjustable-frequency (tunable) crystal for the local oscillator injection, to achieve the final intermediate frequency (IF) of 180 cps (Hz) with a bandwidth of 50 cps (Hz).

The potential stability issues were magnified due to the relative motions of the moon and Earth, which caused a variable Doppler shift in frequency calculated to be a maximum of 327 Hz, putting the receiving signal outside the band of a fixed tuner, thus, requiring the last stage to be tunable.

Limitation on Antenna movement and gain.

Due to the limitations in hardware, the antenna could only move in the azimuth (about the horizon), and could not be elevated. Because of this limitation, the team only had about half an hour each time the moon rose and set to conduct the experiment, as opposed to tracking the entirety of its arc in the sky. This vastly decreased the amount of time to properly conduct the experiment.

The SCR 270/1 radar antenna was insufficient to achieve a positive signal to noise ratio (S/N) for the project, therefore two antennas were assembled together to produce a gain of about 250 above an isotropic radiator, providing a calculated S/N margin of about 15dB above the system and path length losses.

Power, pulse width, and duty cycle.

The transmitter that had a peak power of 3 kw, was modified to produce 15 kw, with a pulse width of 0.05 seconds and a pulse repetition rate of of 4 seconds, allowing the moon to be observed as an isotropic reflector.

System components were being pushed.

At the facility, the team had access to old or used hardware from the war, and found it necessary to modify every element of the system to achieve their goal. There were frequent reports of parts failing due to stresses the setup was putting on them.

Political

Some weren't convinced of the project’s usefulness, and thought it was a waste of time and money. Once achieved, however, the doors opened to a new era – radar astronomy and the space age were born, with new emphasis placed on solid-state research and development to address these new requirements.

What features set this work apart from similar achievements?

There are no prior documented similar achievements; this was the first of its kind, driven by the team’s scientific passion, and a future requirement to develop a defense against rocket (missile) threats. Zoltan Bay and a Hungarian team, achieved a similar result on February 6, 1946. Since their receiver did not have the sensitivity required, and their antenna did not have the gain needed to directly detect the reflected signal, they used an accumulating coulometer to acquire a 30 fold increase in the signal to noise ratio, producing a signal, post processing, 4% above the noise floor. Zoltan Bay acknowledged the prior accomplishment of Project Diana and authenticated it’s findings to be, in fact, correctly presented (see, “Reflection of Microwaves from the Moon”, Z. Bay, link.springer.com, article received 18 th November 1946).

References to establish the dates, location, and importance of the achievement: Minimum of five (5), but as many as needed to support the milestone, such as patents, contemporary newspaper articles, journal articles, or citations to pages in scholarly books. You must supply the texts or excerpts themselves, not just the references. At least one of the references must be from a scholarly book or journal article.

References:

1) Front Page Lead Article, New York Times, January 25, 1946, and also on January 26, 1946.

2) Mofensen, J., “RADAR Echoes From the Moon”, Electronics, Volume 19, April 1946, pp 92 – 98.

3) Gootee, Tom (April 1946), “RADAR reaches the moon”, Radio News, Ziff-Davis Publishing Co., 35 (4), pp. 25 – 27.

4) Dewitt, J. H., Jr.: Stodola, E. K. (March 1949), “Detection of Radio Signals Reflected from the Moon”, Proceedings of the IRE, 37 (3) pp. 229 – 242.

5) http://projectdiana-eme.com

6) Butrica, Andrew J. (1996). To See the Unseen: A History of Planetary Radar Astronomy. NASA. Archived from the original on 2007-08-23, pp 6 - 10.

7) Buderi, Robert, “The Invention that Changed the World”, Chapter 13 (The New Astronomers), Pub. Simon and Schuster, Copyright 1996, ISBN: 0-684-81021-2.

8) “Message to Moon Proves Atmosphere Penetration”, Electrical Engineering, March, 1946, pp 140-141,

The People of Project DIANA

LTC Dr John H. DeWitt, Jr. - Wikipedia link, Harvard link, Obituary, IEEE Member Directory 1996 Entry for John J DeWitt, Jr

Women's History in Engineering and Technology

Celebrating Our History: Inventing Your Future

IEEE Members, SWE Members, and the public were invited to a round table discussion with inspiring women engineers, followed by a reception and networking -- to hear a story and to share a story.

Women’s History Month provides an opportunity for us to celebrate those who have come before us and invented the world in which we live, and to consider the circumstances of their times. At the same time, the discussion encourages us to look forward to the opportunities engineering and professional societies provide for us to fully invent our own future and make an impact upon the world.

Featured Guests: Dr Kahina Lasfer, Dr Paula Muller, Dr Yingying Jennifer Chen, and LTC Dr Kathryn Kennedy Pegues.

Moderator: Dr Katherine Grace August

Several women Engineers and volunteers from the NJ Coast Section collaborated with the Stevens Institute of Technology Student Chapter, and the IEEE History Center to conduct the Event at the campus of Stevens Institute of Technology Lore-El Center during Women's History Month, 27 March 2019. The four IEEE Members were featured in a Round Table discussion including professional membership, mentoring, networking, inventing, and other important topics. Links to key information about the History of Women in Engineering and Technology, and related IEEE Member content is provided herein. The History of Women in Engineering and Technology is now a featured resource on this site connecting our New Jersey Coast Section Members and others with helpful and interesting content and Celebrating the History of Women in Engineering and Technology. We plan content to continue the discussion about Celebrating Our History: Inventing Your Future.

Dr Kahina Lasfer - Data and literature indicate women are at a disadvantage in the engineering field. This presentation will highlight my experiences that provided me more advantages than challenges as a minority female in the engineering workplace. My education and subsequent exposure to diverse and challenging projects provided me the opportunity to work with highly expert professional men including professors, thesis advisors, managers, mentors and co-workers. They were all very supportive in helping me advance in my career in spite of all the challenges that I had to face as a minority female engineer. Dr. Kahina Lasfer is a manager at MTA – New York City Transit, leading systems communications engineering projects through design and construction phases. She holds a PhD in Systems Engineering and a Master’s degree in Computer Engineering from Stevens Institute of Technology. She has over 15 years of experience working as a Software Engineer, Research Engineer, and Manager for Systems Communications Engineering in the railroad industry. Dr. Lasfer also holds a Professional Engineer (P.E.) certification.

Dr Paula Muller - Founder of Sociavi, has a lifelong passion for technology applied to healthcare, starting with her M.S. in Biomedical Engineering in Chile working with blind people, then her work in Switzerland analyzing EEGs to prevent epileptic attacks, followed by her Ph.D. and Post-doc work at Rutgers with Parkinson patients, and most recently at Authentidate with Telehealth products and services. Paula has a vast experience in technology and software development through her engineering positions at several ompanies like Sirus|XM satellite radio, Net-Scale Technologies and Authentidate, among others, and she has extensive management experience through senior positions at Net-Scale Technologies and Authentidate. The business idea for Sociavi evolved from her professional background as well as her strong commitment to family relations and lifetime connections. Thus SOCIAVI, coming from the latin word “share” and “unite”, was born with the goal of keeping seniors and their families closer together.

Dr Yingying Jennifer Chen - Yingying (Jennifer) Chen is a tenured Professor of Electrical and Computer Engineering at Rutgers University and the Associate Director of the Wireless Information Network Laboratory (WINLAB). She also leads the Data Analysis and Information Security Laboratory (DAISY). Her background is a combination of Computer Science, Computer Engineering and Physics. She has co-authored three books Securing Emerging Wireless Systems (Springer 2009) and Pervasive Wireless Environments: Detecting and Localizing User Spoofing (Springer 2014) and Sensing Vehicle Conditions for Detecting Driving Behaviors (Springer 2018), published over 150 journal articles and referred conference papers and obtained 8 patents. Her research has been licensed by multiple companies and reported in numerous media outlets including the Wall Street Journal, MIT Technology Review, CNN, Fox News Channel, IEEE Spectrum, Fortune, Inside Science, NPR, Tonight Show with Jay Leno and Voice of America TV.

LTC Dr Kathryn Kennedy-Pegues - An assistant professor in the Department of Systems Engineering, and Officer in Charge of the Women in Engineering Chapter at the United States Military Academy, West Point. Dr Pegues received her Ph.D. in Industrial Engineering from Clemson University, M.S. Operations Research and M.S. Applied Mathematics from the Naval Post Graduate School. She also serves on the advisory council of the West Point Association of Graduates, and as a volunteer for the West Point Admissions Department identifying and attracting women candidates to the USMA.

IEEE Women's History Month Event - Celebrating Our History, Inventing Your Future -- Round Table at Stevens Institute of Technology. Moderator Katherine Grace August, PhD IEEE NJ Coast Section PACE Chair, AP/EMC/VT Vice Chair, History Committee; Round Table: Kahina Lasfer, PhD MTA, Paula Muller, PhD Sociavi, Yingying Jennifer Chen, PhD Rutgers University, LTC Kathryn Kennedy Pegues, PhD United States Military Academy, West Point.
IEEE Women's History Month Event at Stevens Institute of Technology 27 March 2019 at Lore-El Center for Women's Leadership.

The Round Table Discussion Begins -- click for video.

Round Table Discussion Continues -- click for video.

Round Table Discussion Continues -- click for video.

Round Table Discussion Continues -- click for video.

Link to article from The Institute: IEEE Women in Engineering Committee Celebrates 20 Years [1]

o  Charmain Williams, Sr Manager Women In Engineering Program: c.t.williams@ieee.org

o  Paola Bringas, WIE program Coordinator: p.bringas@ieee.org

·      Main Website for Info: wie.ieee.org

A Role Model and Mentor for our Speaker, Paula Mueller, PhD is Evangelia Micheli-Tzanakou see also IEEE Innovators Archive

Link to Women in Engineering Awards

Link to List of Topics Related to Women

Link to Who Becomes an Inventor in America? The Importance of Exposure to Innovation The Quarterly Journal of Economics, qjy028, https://doi.org/10.1093/qje/qjy028, Published: 29 November 2018

Link to Progress and Potential, OFFICE OF THE CHIEF ECONOMIST IP DATA HIGHLIGHTS Number 2, February 2019

Women's History Month Event Celebrating Our History: Inventing Your Future 27 March 2019.

Interesting Women Engineers

Kate Gleason

Erna Schneider Hoover -- Bell Labs, career, inventor, Wikipedia link

Milestones

New Jersey Coast Milestones

Location of the Milestone is ISEC. Click here for more information and the ISEC web site.

Very interesting IEEE History link: Spaceflight in Silent Film

Milestone Detection of Radar Signals Reflected from the Moon -- Project DIANA -- Celebrating Our History. 17 May 2019 Colts Neck Inn, 18 May 2019 InfoAge Tiros Building.
Volunteers planning the IEEE Milestone celebration for Historic Project DIANA at the Museum InfoAge.

Related Milestones in other Sections

New Jersey Coast Visits with Victor Lawrence, PhD IEEE Life Fellow -- History and Topics of Interest

Mike Molnar and Victor B Lawrence, PhD IEEE Life Fellow discuss Radio History, Professor Dr Louis A Hazeltine and the Neutrodyne Invention at Molnarville, New Jersey 12 March 2019.

Trip to Molnarville, New Jersey, a Visit with Victor B. Lawrence March 2019 to discuss Radio History, Professor Dr Louis A Hazeltine, Neutrodyne, and many other items. Including various items of text, videos, and photos by K.G. August, PhD. Video camera paid for by a grant from IEEE USA with funds donated by IEEE Members.

Click on this Link to see a YouTube video about the Historic Marconi Crystal Radio, from the Navy vessel USS Virginia, World War I.

Click on this Link to see a YouTube video about a Historic Radio Tuner of the type used on the Titanic.

Click on this Link to see a YouTube video about a Historic Theramin with discussion by Mike Molnar Radio Historian and Victor B Lawrence.

Click here for a YouTube video about a Historic Neutrodyne designed by Professor Alan Hazeltine of Stevens Institute of Technology Hoboken New Jersey. Visits with Victor B Lawrence and Mike Molnar, Radio Historian.

Click here for a YouTube video about a Historic Neutrodyne Circuit. Discussion by Victor B Lawrence and Mike Molnar, Radio Historian.

Click here for a YouTube video about a Historic 12 Inch Television. Discussion by Victor B Lawrence and Mike Molnar, Radio Historian.

New IEEE Milestone Neutrodyne Inspires Humanitarian Activities - Collaboration with North Jersey and Stevens Institute of Technology Student Chapter

Click for IEEE Futurecast Milestone Neutrodyne Video

by Katherine Grace August, PhD

IEEE History Inspires Humanitarian Activities - As we have learned from a model in the chapters of IEEE History, Professor Louis A Hazeltine of Stevens Institute of Technology, and his Team who in 1922 developed the Neutrodyne Circuit, it is possible to advance technology for humanity, and to transform the world in which we live by making engineering decisions to benefit humans. The Neutrodyne circuit simplified radio tuning eliminating parasitic oscillation, that terrible squealing and unstable tuning. Because the Hazeltine Team licensed twenty manufacturers, together they were successful in changing the business model for radio. The field was previously monopolized by RCA and their Proprietary solutions for the RCA Super Heterodyne Circuit. By producing ten million Neutrodynes in about three years, Professor Hazeltine’s Team and licensees rapidly expanded the population of people who had access to radios.

Even people on farms and in the mountains could now own a radio. They no longer had to wait for news, to wait to hear what was happening in the towns, and cities, in the Nation’s Capital of Washington DC, across Europe and around the globe. Every person was able to hear the sound bites and make informed decisions when they voted. Even if they could not read, they could gather information and learn. People had wide access to a unifying and common language and vocabulary. Ordinary people could engage in leisure activities listening to music and cultural programming anywhere in the country. Even in the most remote places. People everywhere could actively participate in Democracy.

Caption: Professor Hazeltine, the Neutrodyne Circuit, Stevens Campus - Navy Building

Prior to the commercial development and distribution of the Neutrodyne circuit, only wealthy people with a high level of skill could own and operate radio receivers. Because of the insight and experience Professor Hazeltine had working with the Navy, he keenly recognized the humanity involved in the situation. Every person’s life is valuable. He recognized it was not only the engineering, but also the business model that created disparity – that created a gap between people who have access and those who do not.

Access to technology means life or death, participation in the important aspects of opportunities in our society, in the economy, in education, healthcare, or in the alternative – to experience disparity. He recognized that an expensive solution would necessarily create and attenuate a gulf between humans who can participate, and those who are left out forever because opportunity is passed along to the family, shared by the community, and then to the next generations.

Professor Hazeltine's Lab Notebook, Neutrodyne Logo, Circuit

Caption: Professor Hazeltine Notebooks, Neutrodyne Logo

When Professor Hazeltine embraced a low cost simplified solution, and licensed it making it widely available at a rapid pace, he was a great steward and a role model for the rest of us to use our engineering skills to address the needs of our society and to do it at a lower cost and to do it with a goal – to create a much greater impact, to reduce suffering and to improve opportunity for society.

And Professor Hazeltine illustrated the significance of engineering decisions in transforming opportunities for humans everywhere. Millions of people’s lives were changed and our society was transformed by the remarkable achievements of the Neutrodyne Team. They created mass communication with its vast and immeasurable benefits, and all that enables.

Today, we cannot imagine our world without mass communication. We admire the achievements of the Neutrodyne Team and take notice of the opportunity we have today to make a difference by advancing technology for humanity, by providing lower cost solutions that have a wider impact on society: advance technology for humanity in our community and around the globe.

Within three years of introducing the Neutrodyne, radio ownership grew from 10 percent to 60 percent of the population of North America ushering in Mass Communication that Democratized Politics and forever changed the way people access information, news, music and culture with lasting effects evident in our everyday lives. Even today, we can step up to the challenge and advance technology for humanity, making decisions every day to engineer with a heart. Advancing technology for humanity for the benefit of all the far reaches of the globe, and for our fellow human beings in our own communities.

In the IEEE NJ Coast Section, with our Humanitarian Activities, and our NJ Coast Section SIGHT Group we are very aware of and inspired by the parallels between the legacy of the Neutrodyne and the opportunities for improving technology in our environment today. We are inspired to make excellent engineering decisions for the benefit of humanity – for those with hearing loss, to heal diseases, educate, improve job safety, and to deal with other fundamental needs that must be solved in order to bridge the gap, reduce disparity, welcome humans everywhere to be full participants in society, the economy, in their own lives and in the lives of their families.

In our Humanitarian Activities, Hear, here! we hold as a goal to facilitate providing at least one viable low-cost solution accessible to everyone by promoting IEEE Standards to reduce the impact of proprietary solutions, just as Neutrodyne did in their day. Proprietary solutions in the case of hearing assistance keep technology solutions from helping the people who need them most – people who need to have lower cost access to technology so they can participate fully. There is a vast opportunity for technology to be helpful, since only about 10 percent of the hearing aids needed are produced. In 2020, FDA will allow hearing assistance that doesn’t require prescriptions making this an ideal time to offer new solutions. It is up to us to understand and use our skills to reduce disparities wherever we find them.

We set our goals high and we invite you to join. We aim to raise awareness, capture and share the Stories, be Connectors, and transform opportunities on campuses, in organizations, with company solutions, and to model and inspire others to use our engineering skills to advance technology for humanity in our community and around the globe. That is our model to meet the United Nations Sustainable Development Goals.

Professor Hazeltine, Neutrodyne, Stevens Campus Navy Building

Interview with Professor Dr Don Heirman, 2018 IEEE Richard M. Emberson Award Winner, IEEE Life Fellow and Member of the New Jersey Coast Section -- History in Hearing Aids, Electromagnetic Compatibility, T-Coil Technologies, Mobile Phones, etc.

Professor Dr Don Heirman, IEEE Life Fellow, 2018 Richard M. Emberson Award, discusses Hearing Aid, Electromagnetic Compatibility, Standards, evolving technologies, and more. Photos, Videos, Interviews by K.G. August, PhD.

Professor Dr Don Heirman, IEEE Life Fellow, Founding Member of the EMC Society, and Member of our New Jersey Coast Section shares a wealth of the History in Electromagnetic Compatibility of Hearing Aids and T-Coil Technologies. In a recent interview, Don describes his background, History of Electromagnetic Compatibility, and his own personal experiences with Hearing Aids. Interview, photos, and videos by K.G. August, PhD, (IEEE NJ Coast Section, PACE, AP/EMC/VT, SIGHT Group -- Justice for All project).

Don Heirman's interview when he describes his background and early work. Click link for the YouTube Video.

Don Heirman's interview continues with EMC analysis of medical devices, phones, etc. Click link for the YouTube Video.

Don Heirman's interview continues with his own experience with Hearing Aids. Click link for the YouTube Video.

Don Heirman's interview continues. Click link for the YouTube Video.

Don Heirman's interview continues. Standards. Click link for the YouTube Video.

Don Heirman's interview continues compatibility, interoperability, what about the future of standards. Click link for the YouTube Video.

Major IEEE Award Winners from New Jersey Coast Section

DrRobertWWilson-2018PicnicSpring.jpg
Dr Herwig Kogelnik, IEEE New Jersey Coast Section winner of IEEE Medal of Honor, National Medal of Technology and Innovation, Marconi Prize, Frederic Ives Medal, at Holmdel, New Jersey 2018 presentation about a hero of the Section, Karl Guthe Jansky, and others.

IEEE Medal of Honor: Harald T. Friis, 1955; George C. Southworth, 1963; Rudolf Kompfner, 1973;C. Kumar Patel (C. K. N. Patel), 1989; Alfred Y. Cho, 1994; Herwig Kogelnik, 2001; Gerard J. Foschini (Jerry), 2008

IEEE Alexander Graham Bell Medal: Amos E. Joel, Jr.; William Keister; Raymond W. Ketchledge, 1976; Gerard J. Foschini (Jerry), 2008

IEEE Edison Medal: John R. Pierce, 1963; C. Chapin Cutler, 1981

IEEE Simon Ramo Medal: Victor B. Lawrence, 2007

IEEE Award in International Communication: Eugene O'Neill (E. F. O'Neill), 1971; Victor B. Lawrence, 2004

Harry Diamond Memorial Award: Marcel J. E. Golay, 1951; Harold A. Zahl, 1954; Georg Goubau, 1957; Helmut L. Brueckmann, 1961; John J. Egli, 1966; Harold Jacobs, 1973

IEEE Mervin J. Kelly Award: Harald T. Friis (H. T. Friis), 1964

IEEE Morris N. Liebmann Memorial Award: Harald T. Friis (H. T. Friis), 1939; J. A. Pierce, 1953; Stewart E. Miller, 1972; Willard S. Boyle, 1974; Alfred Y. Cho

IEEE David Sarnoff Award: Rudolf Kompfner (Rudi), 1960; B. C. DeLoach Jr., 1975; H. E. Rowe, 1977; J. M. Manley, 1977; A. G. Fox, 1979; Tingye Li, 1979

Browder J. Thompson Memorial Prize Award: A. W. Randals, 1950; Arthur Karp, 1958

IEEE Eric E. Sumner Award: Debasis Mitra, 1998; Gerard J. Foschini (Jerry), 2004; Krishnan Sabnani, 2005; Reinaldo A. Valenzuela, 2010; Jack H. Winters, 2012

IEEE Lamme Medal: C. Kumar Patel (C. K. N. Patel), 1976

IEEE Richard M. Emberson Award: Don Heirman, 2018

IEEE Edison MedalUrsula Keller, 2019 for a career of meritorious achievement in electrical science, electrical engineering or the electrical arts,sponsored bySamsung Electronics Co., Ltd.,to Recipient URSULA KELLER (FIEEE) — Director of NCCR MUST (Swiss National Centre of Competence for Research in Molecular Ultrafast Science and Technology)—ETH Zurich, Zurich, Switzerland Citation "For pioneering and fundamental contributions to and leadership in useable, compact ultrafast laser technology, enabling applications in metrology, sensing, and biophotonics.”

IEEE Edison Medal 2019 - Ursula Keller. Between 1989 and 1993, Dr Keller conducted her Research at Bell Labs in Holmdel New Jersey. Photo credit: IEEE Award Recipients 2019.

For biographies of the award winners see the further reading section below and click to open the IEEE New Jersey Coast Section Centennial Journal.

Major non-IEEE Award Winners from New Jersey Coast Section

Nobel Prize - Arthur Ashkin, 2018

Link to IEEE Spectrum article on this Nobel Prize

IEEE New Jersey Coast Section celebrates Dr Arthur Ashkin's Nobel Prize.

Dr and Mrs Arthur Ashkin, Nobel Prize Winner, at the Bell Labs Crawford Hill Picnic 2018

Thomas Alva Edison Patent Award - Gerard J. Foschini (Jerry), 2002

Nobel Prize - Robert Wilson, 1978

Nobel Prize - Arno A. Penzias, 1978

Henry Draper Medal - Robert Wilson, 1977

IRE Medal of Honor, Valdemar Poulsen Medal of the Danish Academy of Sciences, Ballentine Medal from the Franklin Institute - Harald T. Friis

Prominent Members

Section Officers

Current section officers:

Irfan Lateef

Ajit Reddy

Filomena Citarella

Claude Martell

Prior section officers:

  • Chair: Dr R. Wyndrum
  • Vice-chair: Dr N. Wilson
  • Secretary: H. Kradjel
  • Treasurer: Dr R. Ting

Past NJ Coast Section Officers

2004 - 2007 Chair Bala Prasanna; Vice Chair Dr Ming Yu; Secretary Bin Yao; Treasurer Dr Rulei Ting

NJ Coast Section Past Officers and Editors
Chair Vice chair Secretary Treasurer "Scanner" Editors Year
Amruthur Narasimhan Bala S. Prasanna Ming Yu Rulei Ting Jose R. Bonilha 1999-2000
Amruthur Narasimhan Bala S. Prasanna Ming Yu Rulei Ting George G. McBride 1998-99
Amruthur Narasimhan Kazem Sohraby Ajay K. Jain Alexander D. Walter George G. McBride 1997-98
Krishnamurthy Raghunandan Kazem Sohraby Mojtaba Shariat Alexander D. Walter vacant 1996-97
William D. Wilber Kazem Sohraby Jagadeesh Pamulapati Alexander D. Walter George G. McBride 1995-96
George G. McBride Alireza Mahmoodshahi Kazem Sohraby William D. Wilber Jaime R. Tormos 1994-95
Umesh J. Amin George G. McBride Sub Krishnamurthy William D. Wilber Jaime R. Tormos 1993-94
Timothy J. Rooney Umesh J. Amin Richard Seyfert, Jr. William D. Wilber Jaime R. Tormos 1992-93
Erwin E. Muller Timothy J. Rooney Richard Seyfert, Jr. William D. Wilber Jaime R. Tormos 1991-92
Gary L. McElvany Erwin E. Muller Richard Seyfert, Jr. Alireza Afrashteh Jaime R. Tormos 1990-91
Meredith Gee Gary L. McElvany Richard Seyfert, Jr. Timothy J. Rooney Umesh J. Amin 1989-90
R.L. Ross Meredith Gee Gary L. McElvany Timothy J. Roony Umesh J. Amin 1988-89
Karen A. Perry R.L. Ross Meredith Gee Christine A. Heaney Timothy J. Rooney 1987-88
Debora A. Berberian Karen N. Archer Meredith Gee David G. Shaw Gary C. Smith 1986-87
David R. Gunderson Debora A. Berberian Larry Bulanda Karen N. Archer David G. Shaw 1985-86
Mari Campanella John R. Baechle Debora A. Berberian You-Hsin E. Yen Kwang S. Park 1984-85
David B. Usechak Michael J. McMahon David R. Gunderson Derek S. Morris Debora A. Berberian 1983-84
Don N. Heirman David B. Usechak Joseph G. Kneuer Michael J. McMahon Pat Trischitta 1982-83
Joseph A. Keilin Don N. Heirman Mary Ellen McNamara David B. Usechak Mike McMahon 1981-82
Miguel A. Carrio Joseph Keilin Don N. Heirman Mary Ellen McNamara Joseph G. Kneuer 1980-81
Joseph Chislow Miguel A. Carrio Joseph Keilin Howard Wichansky Don Heirman 1979-80
Sidney Marshall Joseph Chislow Miguel A. Carrio Joseph Keilin Nicholas LaRocca 1978-79
V. Ramu Ramaswamy Sidney Marshall Joseph Chislow Miguel A. Carrio Seungtaik 1977-78
David Haratz V. Ramaswamy Sidney Marshall R.L. Maybach William Montgomery 1976-77
Victor Ransom David Haratz V. Ramaswamy W. B. Glendinning Joseph Keilin 1975-76
Bruce C. Miller Victor Ransom David Haratz V. Ramaswamy William Stirrat 1974-75
Vasant K. Prabhu Bruce C. Miller Victor Ransom David Haratz J. Gielchinsky 1973-74
Seymour Krevsky Vasant K. Prabhu Bruce C. Miller Victor Ransom Ramu Ramaswamy 1972-73
Detlef C. Gloge Seymour Krevsky Vasant K. Prabhu Bruce C. Miller Salomon Lederman 1971-72
Anthony J. Kazules Detlef C. Gloge Seymour Krevsky Vasant K. Prabhu John A. Soboleski 1970-71
Martin V. Schneider Anthony J. Kazules Detlef C. Gloge Seymour Krevsky John F. Prorok 1969-70
John J. O'Neil Martin V. Schneider Anthony J. Kazules D. Gloge Bruce C. Miller 1968-69
Louis H. Enloe John J. O'Neil Martin V. Schneider Anthony J. Kazules Warren Kesselman 1967-68
Robert Roullette Louis H. Enloe John J. O'Neil Martin V. Schneider Martin V. Schneider 1966-67
Herbert S. Bennett Robert Roullette L. H. Enloe John J. O'Neil John J. O'Neil 1965-66

Herbert S. Bennett was the first NJ Coast Chairman.

Monmouth County Subsection Past Chairmen and Editors
Past Chairmen Past "Scanner" Editors Dates
David C. Hogg 1964-65
Irving Reingold/ Nathan Lipetz 1960-61
Arthur H. Ross 1956-57
George F. Senn 1955-56
William M. Goodall Carl A. Borgeson 1954-55
O. D. Perkins 1953-54
Sloan D. Robertson Archie P. King 1952-53

The first issue of the New Jersey Coast Section newsletter "Scanner" was printed on September 1950.

Archival documents

Humanitarian Activities and Related History

Slide4.jpg

(Including links to IEEE content, USPTO content, and some text, photos, and media by K.G. August, PhD.)

Update October 2019 - Recently, the IEEE NJ Coast Section SIGHT project Hear, here! was selected as one of the five finalists in the University of Maryland Do Good Institute - Do Good Robotics Competition. Team members were invited to Maryland to attend the event and participate in a final Competition. Being among the five finalists with our Here, here! project raised awareness of the issues facing those with hearing loss, demonstrated our commitment to Humanitarian Activities, and resulted in great networking opportunities that will have a lasting impact on our SIGHT and Humanitarian Activities.

Image Caption: Poster presented at the Do Good Robotics Competition - Hear, here!

Then we were invited to attend a Humanitarian Conference Impact.Engineered at NYU Tandem School of Engineering in Brooklyn co-sponsored by ASME, IEEE, and many other organizations. We were able to use our Captioning app to improve speech intelligibility providing ad hoc accommodation during the conference. Many people became aware of the importance of providing accommodation for those with hearing loss and members of our team learned a lot about the Humanitarian Activities community locally and globally.

Image Caption: Using Captions during a presentation at Impact.Engineered at NYU Tandem School of Engineering in Brooklyn October 2019.

Previous:

IEEE Humanitarian Activities Committee and IEEE-USA through Member funding for IEEE PACE, and IEEE NJ Coast Section SIGHT Group for the 'Hear, here! Justice for All' project and Event. The Storytelling Contest submission by the Nyack Mock Trial Team may be viewed at the following link: Nyack Mock Trial Team Storytelling Video.

IEEE and our Members have a long History of involvement in Humanitarian Activities. Many of our Section Members are experienced in Communications, Acoustics, Speech Processing, etc. which relates directly to the topics we address in our Humanitarian Activities. In addition, our IEEE and Communications Technologies History relates to Alexander Graham Bell (a founder of the organization that became IEEE), AT&T, Bell Labs, the Communications Industry, and related topics. Alexander Graham Bell's research organization became what we know of as Bell Labs. In addition, the telephone pioneers of America had a tradition of helping those in need.

Alexander Graham Bell (known as Alec) himself devoted much of his time and effort to Humanitarian Activities including within his profession as a linguist and teacher of the deaf, and through a variety of activities associated with developing techniques and technologies to improve communication. Alec's father-in-law was a very influential person Gardiner Greene Hubbard who financed many of Alec's early efforts in experimentation and technology development. Alec's wife Mabel Gardiner Hubbard Bell, who has been named a Person of National Historic Significance in Canada and who was herself deaf, was one of the first presidents of the early Bell Telephone Company; together the couple held salons, innovated in various fields including flight, founded organizations, and invested in many companies and activities to benefit humanity and further innovation.

We in our Section have become involved with Humanitarian Activities and we have set out a plan and established a new IEEE Special Interest Group for Humanitarian Technologies (SIGHT) Group in the NJ Coast Section. More than ever, access to communication promotes engagement in the economy, education, healthcare, employment, and well being. Humanitarian Activities utilizing our special skills as engineers positions us well to enable interoperable, open source, low cost, networked solutions that engage everyone bridging the gap rather than attenuating disparities of proprietary expensive solutions.

Our first endeavors have been to investigate communication, hearing, and the acoustic scene. This project fits very well into the technical interests and Societies represented in our Section. We conducted an IEEE PACE project in order to develop a wider effort, learn more about Humanitarian Activities, the United Nations Sustainable Development Goals, and form the IEEE SIGHT Group.

Image: The United Nations Sustainable Development Goals.

The recent and ongoing IEEE PACE project: Hear, Here! Justice for All, a Humanitarian Activities Project (HAC), endeavors to understand and raise awareness about how Hearing Loss and related technology, legislation, and social issues, plays a role and impacts people in our Society. In this case, we are investigating the Justice System with a project and event. We have the help of Community, Shareholders, Students, Volunteers, who are IEEE Members and Non-Members. Our upcoming project and event will investigate and raise awareness about how hearing and communication impacts those who are aging and impact on social isolation, depression, health, and dementia.

We establish a goal to move the needle on the United Nations Sustainable Development Goals: 4, quality education, 5 equality for women and girls. 10 reduced inequalities, and 16 peace justice and strong institutions. As members of the largest professional organization for engineers, we can improve access for women and girls and set our SIGHTs on several new initiatives including exploring possibilities for new types of Distinguished Lecturers, supporting conferences and meetings with role model girls and women, documenting and sharing girl's and women's history, promoting innovation and invention by girls and women, and more.

Building on the History of Alexander Graham Bell as a teacher of the deaf, a linguist, humanitarian, social advocate, and technologist, we have collaborated with a Mock Trial Team to understand how the special circumstances of the Justice System and Aging can result in disparity for those with Hearing Loss, to raise awareness, and to propose potential ways to improve the situation.

Hear, Here! Justice for All Videos

For more information about the IEEE NJ Coast Section PACE Humanitarian Activities Project "Hear, here! Justice for All" please click on this link.

For more information about the IEEE NJ Coast Section PACE Humanitarian Activities Project "Sociavi" please click on this link.

We extend our initial efforts to include special populations including those who are aging. Approximately one third of those over 65 have hearing loss. We will collaborate with Sociavi and Paula Muller, PhD to promote Captioning to improve Speech understanding and improved communication.

We extend our efforts to include special populations including Veterans and Military who suffer hearing loss at unprecedented rates. Our colleague LTC Kathryn Kennedy-Pegues, PhD Professor of Systems Engineering at the United States Military Academy, West Point, New York helps us to meet the challenges in this domain.

The IEEE NJ Coast Section PACE, SIGHT Group, and with support of the Humanitarian Activities Committee, conducted an Event on 4 June 2019 in Nyack New York with team members, volunteers, stakeholders, the Mock Trial team, and additional participants. The program included IEEE Photo Booth, Video Booth, Trivia Contest, and presentations. Many informal discussions enabled by the Event provided a great opportunity for people to learn from one another, to share stories, and network. Attendees included but were not limited to: Andrea Composto, Esq. President of the Rockland County Bar Association, the Honorable Dr Duncan Rogers Lee II Esquire, Derek Davis, Equire of Harvard Law School, two additional Judges, multiple attorneys, engineers, Mock Trial team participants, parents, IEEE Members, including engineers, Eamon J Wall, Esquire Senior IEEE Member and Patent Attorney, IEEE NJ Coast Section PACE, SIGHT Group Members and volunteers. Please scroll to see courtroom sketches from the more than year long activities of the growing SIGHT Group team. Please scroll down to see still photos of the activities and Event. Please see the following videos of the Event:

Videos of the Event: 'Hear, here! Justice for All' introduction by Dr Duncan Rogers Lee, II Esquire, Director of the Nyack Mock Trial Team video 1, video 2 Andrea Composto, Esquire, President of the Rockland County Bar Association, video 3 - Derek Davis, Esquire of Harvard Law School Study of the Law, video 4 Derek Davis, Esquire continued , video 5 Derek Davis, Esquire continued , video 6 , video 7 , video 8 , video 9 , video 10 ,

In addition, we have been investigating many issues about Acoustic Analysis, Situation Awareness, and new topics to create a dialog for our Members. Some interesting finds:

Excellent Podcast Series of interest for Acoustics 20KHz.

https://www.20k.org/episodes/birdsong

Justice For All and Courtroom Sketches

Photographs

Bell Telephone Laboratories and Related History

Bell Labs Milestone plaques
  • Bell Telephone Laboratories, Inc. List of Significant Innovations & Discoveries (1925-1983)
  • https://ethw.org/Bell_Labs Provides a very informative History of Bell Labs from the early days when Alexander Graham Bell created a research group that for a time was the greatest in the world.
  • IEEE Alexander Graham Bell Medal was established in 1976 by the IEEE Board of Directors, in commemoration of the centennial of the telephone's invention, to provide recognition for outstanding contributions to telecommunications. The invention of the telephone by Alexander Graham Bell in 1876 was a major event in electrotechnology. It was instrumental in stimulating the broad telecommunications industry that has dramatically improved life throughout the world. As an individual, Bell himself exemplified the contributions that scientists and engineers have made to the betterment of mankind.

IEEE New Jersey Coast Section Celebrating Our History: Inventing Our Future

(Including links to IEEE content, USPTO content, and some text, photos, and media by K.G. August, PhD.)

In an excerpt from the IEEE wiki page on Alexander Graham Bell, we learn that not only did he invent the Telephone, and the telecommunications industry, he was a founder of the professional organization that became the IEEE; 'Bell knew the importance of furthering the profession. He attended the organizational meeting of the American Institute of Electrical Engineers (IEEE’s predecessor society) in May 1884 where he was elected one of six founding vice presidents. And in 1891-92, he served as AIEE president.'

Inspired by Alexander Graham Bell, the History of our Section, its strong connections with Bell Labs, related telecommunications research and industry, and to further Technology for Humanity, we have embarked upon a series of activities and efforts to provide quality experiences to stimulate IEEE Member Vitality, to engage the community, to foster relationships with stakeholders, and to promote innovation for the future. We aim to shine a light on engineering with a heart locally and globally.

We have activities and efforts Celebrating Our History: Inventing Our Future including but not limited to 'Hear, here!' and 'Justice for All' where we gather our skills as engineers to investigate employing mainstream communications infrastructure such as the mobile phone and cloud connectivity, standards, and devices to extend technology for humanity to provide accessible communications and reduce disparities for those with hearing loss. The projects have received funding from IEEE-USA funded by Member donations, and also IEEE-Humanitarian Activities Committee.

IEE-15-CA-391 HAC TypeTreatment CMYK.jpg

Don Heirman interview on Hearing Aids and Electromagnetic Compatibility

(Follow the link above for the videos.) In an interview by K.G. August, PhD with an IEEE New Jersey Coast Section Life Member and a founder of the IEEE EMC Society, Don Heirman, PhD, we learn about his experiences with hearing loss and hearing aid technology. Video camera paid for with grant from IEEE USA funded by donations from IEEE Members.

Don Heirman, PhD, IEEE Life Member and Margaret J Lyons, PE IEEE Senior Member discussing Purdue University and Hearing Aids at Bell Works formerly Bell Labs Crawfords Corner Road, Holmdel, New Jersey.

Interesting Section History Relates to Bell Telephone Laboratories

Patent US1910966A

(Including links to IEEE content, USPTO content, and some text, photos, and media by K.G. August, PhD.)

The Bell Labs Holmdel Complex was constructed between 1959 and 1962, and nearby facilities were founded even earlier providing space and conditions needed for radio research. Much of the history of the New Jersey Coast Section is integral and overlaps with the history of Bell Telephone Laboratories and that history also has a range of geographic affiliations; some of the innovations that were the lifeblood of Bell Telephone Laboratories include speech and sound, radio, radio astronomy, devices, algorithms, methods, standards, media, systems engineering, information theory, etc., and these many achievements contributed to the team, and as such, gave a sense of a shared accomplishment for all who worked for or with Bell Telephone Laboratories over the years. There is a great legacy and optimism about the strength of the team. Many of these achievements have been recognized by IEEE and other organizations through awards and milestones, many of which are on the IEEE History website, and will eventually be organized and linked to the New Jersey Coast Section History page, as many of these reflect achievements of IEEE Members from the Section, or engineers who lived in the geography of the Section. Many activities of the IEEE are organized by Society or Affinity group, but the Sections are particular to a geographic location, a special type of community and we are interested in elevating the quality of Member experiences through the particular characteristics of the geography of the Section.

An intriguing part of the history of Bell Telephone Laboratories along with the pedigree of Alexander Graham Bell himself, involves hearing and speech technologies that assist those with speech or hearing issues -- communications issues. Much of the technology was initially purposeful in the development of the Communications technologies that were a major focus of the company and the industry, and at the same time, efforts were made to provide accessible Communications to persons with issues preventing them from benefiting from general purpose Communications devices. The telephone itself further isolated people with hearing loss, which was ironic given the background of Alexander Graham Bell as a teacher of the deaf.

It is interesting to see how the engineers set out to provide accessibility in Communication to people with disabling conditions. Also, from a 21st Century perspective, it becomes very interesting to see how these technologies overlap with many other fields including but not limited to Biomedical Engineering and Robotics, which are rapidly growing fields. Although at present (April 2018) the New Jersey Coast Section does not have a Chapter of either Biomedical Engineering, nor Robotics, since those areas are experiencing growth worldwide, and since there are engineering achievements in these domains, some of the people notable in the Section and Bell Telephone Laboratories will be featured here along with their achievements so they may be considered from their historic relevance to the present time.

A Member of Bell Telephone Laboratories R. R. Riesz, also recognized by Mike Noll in his list of Significant Innovations & Discoveries (1925-1983), was very involved in innovations that demonstrate the ability of engineering to help people who had needs in order to communicate in their everyday life. One example is represented in two of his patents for Artificial Larynx: US1910966A, and US1836816A. A diagram is presented herein. One does not ordinarily think of Bell Telephone Laboratories as a Biomedical Engineering organization, yet there are many examples.

New Jersey Coast Section Events - Celebrating Our History

The Third Last Crawford Hill Picnic, October 9, 2018

An auspicious occasion held at Bell Labs on Crawford Hill in Holmdel, New Jersey brought together many to Celebrate achievements and enjoy a barbeque lunch. The event featured a presentation remembering Larry Greenstein, “Father of Propagation”, (Larry J. Greenstein Biography), recognizing Sheri Woodward, 30th service anniversary with AT&T, presenting Di Che, with the Marconi Young Scholar Award, and Celebrating Art Ashkin, Nobel Prize in Physics.

Attendees included but were not limited to Dr Arthur Ashkin 2018 Nobel Laureate Physics and Alise Ashkin and Dr Robert Wilson 1978 Nobel Laureate Physics and Elizabeth Wilson.

For the full photo gallery, see the The Third Last Crawford Hill Picnic page.

Awards Banquet 7 June 2018

(With photos by K.G. August, PhD.)

Fundamental Sources of Radiation

GroupPicture-DistinguishedLecturerRamahi.jpg

Great Technology Talk and Meal Series Meet and Greet Distinguished Lecturer Professor Dr Omar M. Ramahi: The Fundamental Sources of Radiation 21 April 2018

(Click link above to View Videos of the Event, discussions by attendees, and to view photo gallery of the event. Videos by Eamon J. Wall, Esq. Photos by K.G. August, PhD.)

2010-04-27: Dr. Omar Ramahi : “What Causes Radiation?” Linked here in PDF format.

Some attendees include:

Thomas M. Willis III https://patents.justia.com/inventor/thomas-m-willis-iii

Margaret Lyons Chair WIE/EdSoc

Alex Walter Esq.

Filomena Citarella Section Treasurer, Vice Chair AP/EMC/VT

Donald Aves

Kit August Section Historian, Secretary AP/EMC/VT

Eamon Wall Esq.

Manu Malek

50th Anniversary of the New Jersey Coast Section May 2015

The 50th Anniversary of the Section was commemorated at a dinner at the Colts Neck Inn, Colts Neck, New Jersey. Highlights included a Keynote presentation by IEEE New Jersey Coast Section Nobel Laureate, Dr Robert W Wilson.

Keynote by Dr Robert W. Wilson Nobel Laureate – Senior Scientist, Smithsonian Astrophysical Observatory, Harvard Smithsonian Center for Astrophysics

Recently, Dr Wilson was technical leader of the Sub-Millimeter Array radio telescope. His early work at Bell Labs was in the field of Galactic radio astronomy and precision measurement of radio source strengths. He is best known for his part in the 1964 discovery of the cosmic background radiation thought to have originated in the early stages of the big bang. He helped to extend radio spectroscopy to short millimeter wavelengths discovering interstellar molecules including Carbon Monoxide. Molecular astronomy has increased our knowledge of how stars form out of interstellar gas. While at Bell Labs, he measured earth-space propagation for satellite communication, made infrared propagation measurements, and worked in wireless communications and optical networking.

He is co-recipient of the Henry Draper Medal from the U.S. National Academy of Science and the Herschel Medal from the Royal Astronomical Society, London and the 1978 Nobel Prize in Physics. Dr Wilson received a BA from Rice University in 1957 and a PhD from California Institute of Technology in 1962.

See the 50th Anniversary of the New Jersey Coast Section for the full photo gallery of the event. (Photos by K.G. August, PhD.)