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        <title><![CDATA[Stories by Computer History Museum on Medium]]></title>
        <description><![CDATA[Stories by Computer History Museum on Medium]]></description>
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            <title><![CDATA[A Year with AI]]></title>
            <link>https://medium.com/chmcore/a-year-with-ai-7b44a45882e4?source=rss-de2302dabfe4------2</link>
            <guid isPermaLink="false">https://medium.com/p/7b44a45882e4</guid>
            <category><![CDATA[agentic-ai]]></category>
            <category><![CDATA[ai]]></category>
            <category><![CDATA[ai-agent]]></category>
            <category><![CDATA[generative-ai-tools]]></category>
            <category><![CDATA[joanna-stern]]></category>
            <dc:creator><![CDATA[Computer History Museum]]></dc:creator>
            <pubDate>Fri, 22 May 2026 21:06:35 GMT</pubDate>
            <atom:updated>2026-05-22T21:08:01.352Z</atom:updated>
            <content:encoded><![CDATA[<p>By CHM Editorial</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*z9GnE8LgXiLsJgh-iIptuA.jpeg" /></figure><p>What is it like to turn over your life to artificial intelligence for an entire year? Emmy Award–winning tech journalist Joanna Stern found out.</p><p>Stern was on stage at CHM Live on May 19, 2026, to share insights from her new book, I Am Not a Robot: My Year Using AI to Do (Almost) Everything, in a discussion with The Verge cofounder and editor-in-chief Nilay Patel.</p><p>The event was sponsored by the Patrick J. McGovern Foundation.</p><h3>Losing Control</h3><p>Patel opened the conversation by asking what’s up with students booing AI advocates at their graduation ceremonies? Stern recalled that only a year ago, her Union College commencement speech about AI had inspired only yawns, but young people are much more aware today.</p><p>There’s a backlash growing among young people, even those who actively use AI. Their concerns range from job displacement, the ethics of training models on creative work, the environmental impact of data centers, and wariness shaped by having grown up as guinea pigs for social media.</p><p>That skepticism reflects a difference between AI and earlier tech innovations. Stern and Patel remembered how tools like smartphones empowered users to create and explore. People were in control, said Stern, but with AI, the tools are increasingly acting on our behalf.</p><p>For AI to be most useful, Stern said, people often have to adapt themselves to the technology — to essentially become a data set. She shared an example from her book — a wearable device that recorded her conversations and generated summaries and to-do lists. While powerful, it raised significant privacy concerns and underscored the trade-offs between convenience and personal control.</p><p>Many jobs will increasingly outsource tasks to AI systems, a bigger shift than earlier technological disruptions. What’s even more worrisome is when we outsource our own thinking.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FHpu2QowVZlA%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DHpu2QowVZlA&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FHpu2QowVZlA%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/69edadc3a371395abd4e2de82407be44/href">https://medium.com/media/69edadc3a371395abd4e2de82407be44/href</a></iframe><h3>Setting Boundaries</h3><p>Stern’s goal was to incorporate as much AI into her life, exploring technologies like robotics, autonomous vehicles, and more. She framed her approach around systems that can see, hear, think, and act like humans. And it was important to set boundaries.</p><p>Some things, Stern found, should not be handed over, especially personal communication. Using AI for automated email responses still feels generic and impersonal, and maintaining genuine human connection required her own voice. Other tools, like an AI-powered toothbrush, fell short and are clearly not ready for prime time.</p><p>Her family became an essential part of her story. Watching her children interact with AI, including using a self-driving Waymo car on vacation, helped Stern see AI tools through their eyes and shapes how she thinks about a future where its embedded in so much of their lives.</p><p>She wanted to understand the pull of AI relationships that people are experiencing today, but she did NOT introduce her AI “boyfriend” to her kids.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FD_WFLwTffQ8%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DD_WFLwTffQ8&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FD_WFLwTffQ8%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/2044db5d2e3998ac3a6c99556d6e776a/href">https://medium.com/media/2044db5d2e3998ac3a6c99556d6e776a/href</a></iframe><h3>Our AI Future</h3><p>Stern is optimistic about AI’s potential in areas like making transportation safer, enhancing education, and advancing important discoveries in healthcare. While she loves her computer, she predicts that the next generation of computing may move beyond screens entirely. Today’s children are already interacting with technology through voice and touch rather than keyboards. New tools, such as wearable devices and smart glasses, point toward a more ambient form of computing — systems that continuously observe and interpret the world. Conversational interaction with AI is already becoming natural.</p><p>AI played a significant role in Stern’s professional work. While she wrote her book herself, AI tools were invaluable for editing, analyzing transcripts, structuring ideas, and even helping launch a business around the project. From setting up payroll systems to designing a website, AI made complex processes feel more manageable and accessible.</p><h3>The Business of AI</h3><p>Stern says that AI companies want to make AI that is smarter than any humans ever could be. But she thinks the models we have can do enough already.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2F9jtTiSbEiMg%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3D9jtTiSbEiMg&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2F9jtTiSbEiMg%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/a1dad32b1030d2e329c391fa7380e3c3/href">https://medium.com/media/a1dad32b1030d2e329c391fa7380e3c3/href</a></iframe><p>Despite rapid innovation, Stern does not see AI replacing the smartphone anytime soon. She described the phone as “the pinnacle computer,” a platform that democratized access to technology in an unprecedented way. AI developments are more likely to build on that foundation than replace it.</p><p>Closing with questions from the audience, Stern had advice for young people wondering how to navigate the rapidly changing AI landscape: keep reading, and keep thinking critically.</p><h3>Watch the Full Conversation</h3><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2F31FNULsvGwM%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3D31FNULsvGwM&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2F31FNULsvGwM%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/396230068ed04e873958d5c3d6d1ca82/href">https://medium.com/media/396230068ed04e873958d5c3d6d1ca82/href</a></iframe><img src="https://medium.com/_/stat?event=post.clientViewed&referrerSource=full_rss&postId=7b44a45882e4" width="1" height="1" alt=""><hr><p><a href="https://medium.com/chmcore/a-year-with-ai-7b44a45882e4">A Year with AI</a> was originally published in <a href="https://medium.com/chmcore">Core+</a> on Medium, where people are continuing the conversation by highlighting and responding to this story.</p>]]></content:encoded>
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        <item>
            <title><![CDATA[CHM and Seagate: Preserving Digital History]]></title>
            <link>https://medium.com/chmcore/chm-and-seagate-preserving-digital-history-ee4eff2d3017?source=rss-de2302dabfe4------2</link>
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            <dc:creator><![CDATA[Computer History Museum]]></dc:creator>
            <pubDate>Wed, 20 May 2026 15:56:34 GMT</pubDate>
            <atom:updated>2026-05-20T15:57:29.015Z</atom:updated>
            <content:encoded><![CDATA[<p>By CHM Editorial</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*sJQAi20Hnx0KHwvY3ItZ0w.jpeg" /></figure><p>The Computer History Museum extends its sincere thanks to Seagate Technology for its recent donation of one petabyte of storage to help preserve our world’s digital legacy.</p><p>Through its exhibits and programs, CHM celebrates both the history and the future of computing. From the room-sized mainframes of the 1950s and 1960s to the smartphones we carry today, the Museum brings the story of computing to life.</p><p>Behind that seven-decade history, however, is another story — one that unfolds largely behind the scenes: the challenge of storage. How do we preserve the information these machines processed, generated, and made possible?</p><p>After many early experiments, the 1956 IBM RAMAC hard drive helped establish the model for modern disk-based storage. To document that evolution, CHM hosts a dedicated Storage Special Interest Group (SIG), and its permanent collection includes more than 150 hard drives from dozens of manufacturers, beginning with some of the earliest prototypes.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/600/1*0lBS3l4qlmJDOOZ4X7xd8g.jpeg" /><figcaption>CHM preserves the computer storage story beginning with the very first hard drive: IBM’s 1956 RAMAC.</figcaption></figure><p>That history is not just on display — it is brought to life each week by knowledgeable volunteers who conduct the world’s only live <a href="https://computerhistory.org/tours/">demonstration of a RAMAC</a> hard drive every Wednesday at the Museum.</p><h3>The Future Arrives</h3><p>On February 11, 2026, a critical shipment arrived at CHM. It wasn’t a vintage computer or a rare manuscript — it was the storage infrastructure needed to preserve those treasures for generations to come.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*97MAWow60H-oAsqkfyydGA.jpeg" /><figcaption>A Seagate 24TB Exos hard drive powered by Mozaic technology.</figcaption></figure><p>Through a generous donation, Seagate provided 24TB Exos hard drives powered by Mozaic technology, the breakthrough innovation redefining areal density and driving Seagate’s capacity leadership in the AI era. More than just hardware, these high-capacity drives represent the technology that helps safeguard history, unlock the enduring value of data, and ensure the past remains accessible in an increasingly digital world.</p><h3>Why Does a Museum Need a Petabyte?</h3><p>You might wonder why a museum dedicated to history needs a petabyte of modern storage. The answer lies in our massive digitization efforts. CHM currently manages nearly two linear miles of physical documentation that is being systematically digitized. Generous donors have funded these projects, allowing us to turn fragile paper and film into stable digital files.</p><p>But digitization is only the beginning. Once a document or video is scanned, it enters CHM’s digital repository, where it must be stored, managed, and prepared for long-term access. German Mosquera, CHM’s Director of Technology Operations, explains that Seagate’s Exos drives are a key part of a major storage upgrade, supporting the server environment that handles the queues for CHM’s oral histories and other high-resolution video and media collections. This is one of the most active parts of the system — where data is staged, organized, and readied for ingestion before moving to its final destination and becoming accessible to the public.</p><h3>Tackling the Digital Dark Age</h3><p>As we move further into the 21st century, we face a growing threat often referred to as the Digital Dark Age: the risk that vital pieces of our digital cultural heritage could be lost as hardware ages, fails, or the software needed to access them becomes obsolete. Hard drives, like all physical infrastructure, have a finite lifespan and typically must be replaced every five years to ensure continued reliability and access.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/800/1*FAiZE7JYujkXQImbJOgXUg.png" /><figcaption>Introduced in 1980, the ST-506 was the first 5.25-inch hard disk drive. It was developed by Shugart Technology (now Seagate Technology) and was the first full-height 5.25-inch HDD designed for personal computers, a major milestone in storage history. CHM #<a href="https://nam10.safelinks.protection.outlook.com/?url=https%3A%2F%2Fwww.computerhistory.org%2Fcollections%2Fcatalog%2F102672976%2F&amp;data=05%7C02%7Chhackford%40computerhistory.org%7C41b88d4d89c64b9bf15908deabb4fc56%7Cb6a9c12a29ee4c5f8f93f0d7a8e2db2f%7C0%7C0%7C639136990985956024%7CUnknown%7CTWFpbGZsb3d8eyJFbXB0eU1hcGkiOnRydWUsIlYiOiIwLjAuMDAwMCIsIlAiOiJXaW4zMiIsIkFOIjoiTWFpbCIsIldUIjoyfQ%3D%3D%7C0%7C%7C%7C&amp;sdata=kkyAoYk9uwGysvoylaPsiOgF5IyR5QwpoEwoXXlohk8%3D&amp;reserved=0">102672976</a></figcaption></figure><p>Seagate’s donation helps CHM meet this challenge head-on in three critical ways:</p><ul><li>Modernize essential infrastructure: By replacing drives that are approaching the end of their dependable life, the Museum can strengthen the reliability of the systems that protect its digital collections.</li><li>Support continued growth: Since 2020, CHM’s storage needs have grown by roughly 70TB. With higher-quality video scans and an expanding volume of oral histories, the Museum anticipates adding at least 20TB of new data each year through 2030.</li><li>Improve efficiency and reduce cost: This donation also allows CHM to retire older storage systems, lowering licensing and support expenses while simplifying ongoing operations.</li></ul><h3>Opening the Vault</h3><p>All of this behind-the-scenes storage work serves a very public purpose. With the recent launch of <a href="https://www.computerhistory.org/collections/catalog">OpenCHM</a> — a digital portal featuring a new search engine and API — the Museum is expanding fine-grained access to its collections in powerful new ways. For a researcher in Nairobi or a student in Tokyo, the data stored on Seagate Exos drives helps make CHM’s collections discoverable, accessible, and usable from anywhere in the world.</p><p>Seagate has long championed the value of data — a theme that resonates deeply with CHM’s mission to decode technology for everyone. Data is more than ones and zeroes; it is the living record of human ingenuity and the technological breakthroughs that have shaped the past half-century. It includes extraordinary historical artifacts, from the source code used on the Apollo Guidance Computer that helped put humans on the Moon to some of the earliest sketches of the integrated circuit and microprocessor. It also includes more than 1,200 oral histories from pioneers in computing, storage, and semiconductors in CHM’s collection — the largest of its kind in the world. And that record continues to grow as we capture the voices of the people who helped invent our data-driven world.</p><h3>A Partnership for Posterity</h3><p>As CHM looks toward 2030, its digital footprint will continue to expand. A dependable foundation of storage infrastructure means one less obstacle in the urgent work of preserving the digital record of our time.</p><p>To the team at Seagate: Thank you for being our partners in preservation. By helping provide the technology needed to store and safeguard these digital artifacts today, you are helping ensure that the story of computing — and the ways it has shaped every aspect of modern life — can be discovered, studied, and understood for generations to come.</p><p>Main image: CHM’s Shustek Research Archives.</p><p><em>Originally published at </em><a href="https://computerhistory.org/blog/hearing-tech-history/"><em>https://computerhistory.org</em></a><em> on May 20, 2026.</em></p><img src="https://medium.com/_/stat?event=post.clientViewed&referrerSource=full_rss&postId=ee4eff2d3017" width="1" height="1" alt=""><hr><p><a href="https://medium.com/chmcore/chm-and-seagate-preserving-digital-history-ee4eff2d3017">CHM and Seagate: Preserving Digital History</a> was originally published in <a href="https://medium.com/chmcore">Core+</a> on Medium, where people are continuing the conversation by highlighting and responding to this story.</p>]]></content:encoded>
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            <title><![CDATA[2026 CHM Awards Ceremony]]></title>
            <link>https://medium.com/chmcore/2026-chm-awards-ceremony-8cb33cb136f8?source=rss-de2302dabfe4------2</link>
            <guid isPermaLink="false">https://medium.com/p/8cb33cb136f8</guid>
            <category><![CDATA[internet-archive]]></category>
            <category><![CDATA[palm-pilot]]></category>
            <category><![CDATA[computing-history]]></category>
            <dc:creator><![CDATA[Computer History Museum]]></dc:creator>
            <pubDate>Mon, 18 May 2026 17:44:32 GMT</pubDate>
            <atom:updated>2026-05-18T17:45:43.622Z</atom:updated>
            <content:encoded><![CDATA[<p>By CHM Editorial</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*XTNTOQJg9DK_EN99-hXavQ.jpeg" /></figure><p>On April 25, 2026, just past his one-year anniversary at CHM, CEO and President Marc Etkind kicked off the annual Fellow Awards ceremony. Five new CHM Fellows joined a distinguished group of technology pioneers and the very first Silicon Valley Laureate was honored. In their acceptance remarks, all the honorees attributed their success to teamwork and collaboration.</p><h3>The Palm Team</h3><blockquote>Great cultures build great teams that accomplish great things. —<em> Ed Colligan</em></blockquote><p>CHM Trustee Eileen Fagan introduced the Palm Team — <a href="https://computerhistory.org/profile/jeff-hawkins-2/">Jeff Hawkins</a>, <a href="https://computerhistory.org/profile/donna-dubinksy/">Donna Dubinsky</a>, and <a href="https://computerhistory.org/profile/ed-colligan-2/">Ed Colligan</a> — who were being recognized for “development of groundbreaking, commercially successful handheld computers and smartphones, which established the foundation for today’s mobile computing.”</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FecICRiGmlPA%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DecICRiGmlPA&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FecICRiGmlPA%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/c3178b6c1247eba94e8eadf74c883eb2/href">https://medium.com/media/c3178b6c1247eba94e8eadf74c883eb2/href</a></iframe><p>Rob Haitani, senior UX design manager for Ring and also at Palm and Handspring, presented the Fellow Awards to the Palm Team. He credited Jeff with teaching him that creativity is “an act of reduction” to reveal new possibilities, Donna with guiding teams through the precarious startup years with empathy, and Ed with leading marketing with insight, humor, and a “sense of controlled insanity.” Their complementary strengths, he said, drove Palm and Handspring’s success and made people feel they were part of something that truly mattered.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*Kw1__0PM8h7vnw5dROrI2Q.jpeg" /><figcaption>Ed Colligan accepts his 2026 CHM Fellow Award.</figcaption></figure><p>Accepting his award, Colligan emphasized the extraordinary teams at Palm and Handspring, who created many of the ideas and core design elements that shaped the mobile devices we use today — joking that it might be their fault if no one makes eye contact at family dinners anymore. He appreciated that the team award pushed back against the industry’s growing obsession with the “lone genius” and invited Palm and Handspring alumni in the room to stand and be recognized.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*6w4aVhoPBIHC3F6nG5ERsA.jpeg" /><figcaption>Donna Dubinsky accepts her 2026 CHM Fellow Award.</figcaption></figure><p>Dubinsky reflected on what it truly means to operate at the frontier — intensely competitive, filled with highs and lows. For her, the greatest highs came from seeing their product being used “in the wild” by someone who was not a friend or family member. The lows included technical failures, vendor problems, recessions, and hard decisions. Courage, resilience, persistence, adaptability, and flexibility were the only ways to overcome the barriers inherent in creating something truly new. In the end, she said, the chance to have an impact on people’s lives has been the thrill of a lifetime.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*DcCUpq4PSNiCSIjABMCwQA.jpeg" /><figcaption>Jeff Hawkins accepts his 2026 CHM Fellow Award.</figcaption></figure><p>Hawkins noted that entrepreneurs don’t invent the future so much as they see it coming and “help it arrive a little sooner and a little better.” His epiphany in 1991 was the idea of a computer in your pocket that could access information about the world. Technology had to evolve to eventually make that possible, but the human desire for information has always powered innovation. He reflected on the unanticipated consequences that once people had constant access to information, some chose to make it addictive — a problem the world is only now beginning to reckon with. But, he believes the overall impact of these devices has been profoundly positive.</p><h3>John Chowning</h3><blockquote>Aesthetics is difficult to quantify, we simply know when it is right. — <em>John Chowning</em></blockquote><p><a href="https://computerhistory.org/profile/john-chowning-2/">John Chowning </a>was recognized “for the invention of audio FM synthesis, which transformed the musical landscape using computers.”</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FhXvuZROErNU%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DhXvuZROErNU&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FhXvuZROErNU%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/48c30cbb2f04db38985ae8865db1cf14/href">https://medium.com/media/48c30cbb2f04db38985ae8865db1cf14/href</a></iframe><p>Chris Chafe, professor and chair of the Music Department at Stanford University presented the Fellow Award to Chowning, who he called “an inventor and musician with an insatiable appetite for new ideas.” The experiments on electronic music that Chowning began in the 1960s laid the foundation for entire fields at the intersection of art and science, ideas that are now so embedded in contemporary music that they are nearly ubiquitous. In 1974, he cofounded the Stanford Center for Computer Research in Music and Acoustics (CCRMA), a magnet for extraordinary talent nurtured by Chowning’s deep commitment to mentorship.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*VhIfR9HpG0IKRmyK3BcOPA.jpeg" /><figcaption>John Chowning accepts his 2026 CHM Fellow Award.</figcaption></figure><p>Accepting the award, Chowning described how his work and that of others has democratized computer music, starting with a collaboration with Yamaha engineers in the late ’70s and early ’80s that produced the first low-cost digital synthesizer. Today, FM synthesis lives on in software embedded throughout digital music production. He noted that technological impact is unpredictable, but in the age of AI, he believes that music resists shortcuts and that aesthetics are difficult to quantify. Transcending language and serving as a powerful bond across cultures, music reminds us, said Chowning, of the enduring importance of marrying technology with the humanities.</p><h3>Brewster Kahle</h3><blockquote>Pick a big problem and then try to make some progress at it. — <em>Brewster Kahle</em></blockquote><p>Before <a href="https://computerhistory.org/profile/brewster-kahle-2/">Brewster Kahle</a> received his award, musician and humanitarian Peter Gabriel offered a special recorded congratulations for Kahle’s profound and important work opening access to the world’s digital history.</p><p>Kahle was honored “for pioneering roles in online search engines, and in digital preservation and open access to knowledge provided by the Internet Archive.”</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FzGxk_qV29FM%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DzGxk_qV29FM&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FzGxk_qV29FM%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/272acdb4a4c5d4cfda5c20460985073a/href">https://medium.com/media/272acdb4a4c5d4cfda5c20460985073a/href</a></iframe><p>Mitch Kapor, founding partner at Kapor Capital and 1996 CHM Fellow, presented the Fellow Award, noting that Kahle’s work reflects a clear and consistent belief that knowledge is a public good that should be open and accessible. That commitment was already evident in the 1980s at Thinking Machines and at WAIS Inc., where his work anticipated many of the core functions of today’s web and helped lay the conceptual groundwork for our contemporary information ecosystem. His vision expanded dramatically in 1996 with the founding of the Internet Archive, now the world’s leading digital repository. The Archive made it possible to preserve a historical record of the web that would otherwise have vanished. Beyond preservation, his efforts have continually advanced digital rights.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*g-uzujJNUkRgvyk9HGRPGw.jpeg" /><figcaption>Brewster Kahle accepts his 2026 CHM Fellow Award.</figcaption></figure><p>Accepting the award, Kahle explained that he has found meaning in his life by following the advice to do something that matters, even if you know you’ll never finish it. For him, that meant pursuing the dream of universal access to human knowledge. He has pursued technology that made people smarter, more capable, and more informed, as well as open systems that people could trust and build on. He believes that one of today’s great challenges is figuring out how to harness new AI capabilities in an environment that’s increasingly dominated by monopolies. The question, he says, is whether the ecosystem stays open enough to benefit everyone.</p><h3>Mark Stevens</h3><blockquote>We haven’t seen anything yet. — <em>Mark Stevens</em></blockquote><p>Eileen Fagan introduced the new Silicon Valley Laureate Award, which honors leaders who have made an enduring and positive impact on the entrepreneurial ecosystem that has enabled Silicon Valley’s leadership in today’s digital age. Venture capitalist Mark Stevens received the award “for early and enduring investments in transformative technology companies, and for shaping the entrepreneurial ecosystem that powers the modern digital economy and era of artificial intelligence.”</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2F76V4rED_BnM%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3D76V4rED_BnM&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2F76V4rED_BnM%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/83669e2b4faf52dac1c72f2a17136f9c/href">https://medium.com/media/83669e2b4faf52dac1c72f2a17136f9c/href</a></iframe><p>Presenting the award, Fagan noted Stevens’s early investments in Google, YouTube, Yahoo, and Nvidia while a partner at Sequoia Capital and his mentorship of entrepreneurs at S-Cubed Capital today.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*eYJPZkqEzy2RJVzm1EtO0w.jpeg" /><figcaption>Mark Stevens accepts his CHM award for the 2026 Silicon Valley Laureate.</figcaption></figure><p>In 1989, when he began his career in venture capital, said Stevens, it was still a tiny corner of the global financial system. Don Valentine and Pierre Lamond at Sequoia Capital took a chance on him and subjected him to an intense — and unforgettable — tutelage. Looking back over his 45-year career in technology, he believes we haven’t seen anything yet. Although he has been deeply involved in AI, the speed and magnitude of its growth have been astonishing, and he believes the world will be largely unrecognizable a decade from now. Silicon Valley will continue at the forefront of this technological shift as it has for every other. But leadership brings responsibility, and we cannot afford complacency or arrogance, said Stevens. We must actively nourish entrepreneurship, protect the ecosystem that enables it, and earn the right to continue to be the place to build the future.</p><h3>Power the Future</h3><p>Marc Etkind closed the evening by launching the public phase of CHM’s capital campaign, Power On: Decoding the Past, Igniting the Future. With the help of generous donors, the Museum has already been able to make an impact. <a href="https://computerhistory.org/power-on/">Learn more and contribute</a> by June 30, 2026, to support CHM as a trusted voice during this time of ever-accelerating change.</p><h3>Sponsorship</h3><h4>Fellows Sponsor</h4><figure><img alt="" src="https://cdn-images-1.medium.com/max/229/0*bxl7G8z6W6qo2X9E.jpg" /></figure><h4>Table Sponsors</h4><figure><img alt="" src="https://cdn-images-1.medium.com/max/300/0*ImiAs0j-FT03TR9-.png" /></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/300/0*Xi5_8p5cMfcTNc90.png" /></figure><p>Colligan-Burns Family Fund<br>Yogen and Peggy Dalal<br>Donna Dubinsky and Len Shustek<br>Eileen Fagan and Andy Cunningham<br>Ken Goldman and Susan Valeriote<br>Jeff Hawkins and Janet Strauss<br>Meredith and Ray Rothrock<br>Stephen S. and Paula K. Smith</p><h4>Tribute Gift Sponsors</h4><p>John and Maureen Chowning<br>The Cismas Foundation<br>Rob and Yukari Haitani<br>Franklin P. Johnson, Jr.<br>Mary Meeker<br>Paul and Antje Newhagen<br>Greg and Laurie Papadopoulos<br>Harry and Carol Saal<br>Silicon Valley Community Foundation<br>Diane L. Souvaine<br>Marty and Sandy Tenenbaum<br>Jan and Sylvia Uddenfeldt</p><h4>Wine Sponsor</h4><p>House Family Vineyards</p><h4>Special Thanks</h4><p>Allegra Entertainment &amp; Events<br>Catered Too, Inc.<br>Global Gourmet Catering</p><h3>Watch the Full Event Video</h3><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FwUQM6gWya2I%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DwUQM6gWya2I&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FwUQM6gWya2I%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/ca585f731e554fc7c7e8a6a0e977ab96/href">https://medium.com/media/ca585f731e554fc7c7e8a6a0e977ab96/href</a></iframe><p>Main image: CHM President and CEO Marc Etkind kicks off the 2026 CHM Awards celebration.</p><p><em>Originally published at </em><a href="https://computerhistory.org/blog/hearing-tech-history/"><em>https://computerhistory.org</em></a><em> on May 1, 2026.</em></p><img src="https://medium.com/_/stat?event=post.clientViewed&referrerSource=full_rss&postId=8cb33cb136f8" width="1" height="1" alt=""><hr><p><a href="https://medium.com/chmcore/2026-chm-awards-ceremony-8cb33cb136f8">2026 CHM Awards Ceremony</a> was originally published in <a href="https://medium.com/chmcore">Core+</a> on Medium, where people are continuing the conversation by highlighting and responding to this story.</p>]]></content:encoded>
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            <title><![CDATA[A Historic Pixel Art Exhibition]]></title>
            <link>https://medium.com/chmcore/a-historic-pixel-art-exhibition-c0faf5d464cf?source=rss-de2302dabfe4------2</link>
            <guid isPermaLink="false">https://medium.com/p/c0faf5d464cf</guid>
            <category><![CDATA[computing-history]]></category>
            <category><![CDATA[computer-graphics]]></category>
            <category><![CDATA[nasa]]></category>
            <dc:creator><![CDATA[Computer History Museum]]></dc:creator>
            <pubDate>Fri, 10 Apr 2026 16:48:14 GMT</pubDate>
            <atom:updated>2026-04-10T16:50:11.443Z</atom:updated>
            <content:encoded><![CDATA[<p>By Catharina Santasilia</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/700/1*IoJxWmCeyK7PFuqtYYLojw.jpeg" /></figure><h3>The 1981 Framebuffer Show</h3><p>In 1981, a groundbreaking show featured digital art on monitors connected to framebuffers and a computer. This marked the first time digital images were displayed in their native electronic form, a practice that has since become standard worldwide. The exhibition, held at the Association for Computing Machinery’s SIGGRAPH conference in Dallas, was conceived by a small team of tech pioneers who defied all odds to make it happen.</p><p>The small team was based out of the Computer Graphics Lab at NASA’s Jet Propulsion Laboratory (JPL) in Pasadena. It included the lab’s manager, Robert Holzman; computer scientist Jim Blinn; systems engineer Julian Gomez; systems engineer Eric Levy; independent artist David Em, who was the lab’s Artist-in-Residence; and James Seligman, Em’s producer.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*pHvK_27POfkB2CA8WGb_Pw.jpeg" /><figcaption>Left image: Four of the key producers of the 1981 Framebuffer Show at the JPL Graphics Lab; from left to right: James Seligman, Julian Gomez, and David Em. Courtesy of David Em, 1981. Right image: Jim Blinn in front of the computer setup in the Graphics Lab, creating simulations of the Voyager flybys. Courtesy of Jim Blinn, 1981.</figcaption></figure><p>The digital images displayed were primarily by Em, Blinn, and the New York Institute of Technology’s Computer Graphics Lab (NYIT or New York Tech CGL). The exhibition was viewed by thousands of attendees and paved the way for future purely electronic exhibitions.</p><p>While computer-generated art had been exhibited prior to this show, such as at the Howard Wise Gallery in New York (April 1965) and the Cybernetic Serendipity exhibition (August to October 1968) at the Institute of Contemporary Arts in London, the artworks exhibited there, for the most part, were works on paper.</p><h3>The Key Players</h3><p>Robert Holzman was not a typical corporate manager; he was an engineer with a background in deep space photography. Holzman’s genius was to hire talented people, then step back and let them do what they did best, while shielding them from the federal bureaucracy at the JPL. He was also a visionary with a passion for the arts. Holzman later married Patric Prince, a key figure in digital art exhibitions throughout the 1980s.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*9PIwl0NSVmdmTy00pKxKTg.jpeg" /><figcaption>Robert Holzman, the JPL Graphics Lab manager, 1981. Photo courtesy of David Em.</figcaption></figure><p>In 1975, Holzman sought funding within NASA to establish what would become the JPL Computer Graphics Lab, a research facility focused on creating deep-space simulations and media for public dissemination. These would eventually be viewed by billions of people worldwide.<a href="https://computerhistory.org/blog/a-historic-pixel-art-exhibition/#note1">[1]</a></p><p>Meanwhile, around the same time, digital artist David Em was looking for a high-tech institution in the United States with which he could collaborate to pursue his interest in digital art. He had recently built a framebuffer (the key memory component of graphics cards and GPUs) from scratch; however, he quickly realized that to create the art he envisioned, he needed to be affiliated with a large institution that could provide access to higher-end computer hardware and sophisticated software.</p><p>Em contacted JPL and got Holzman on the other end of the phone — shortly after, Em visited Holzman in his office and they spent the afternoon talking about art. As they were wrapping up, Holzman said to Em, “You know, if I ever do get funding, it would be great to have an Artist-in-Residence, would you be interested in doing that?”</p><p>About a month later, Holzman secured funding for his Graphics Lab at JPL, and in January of 1976, Em moved to Pasadena; however, it took almost another year and a half before JPL allocated space for the lab on its campus, the machines were up and running, and staff were hired. By the summer of 1977, Jim Blinn had arrived, and shortly after that, Julian Gomez.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*G3AIf6iiCthubv7WzYP_VQ.jpeg" /><figcaption>The Jet Propulsion Laboratory main campus, Pasadena, California. The Graphics Lab relocated in the spring of 1981 from Building 264, where all artworks had been created since 1977, to Building 233, where the 1981 Framebuffer Show was organized. Image courtesy of NASA/JPL.</figcaption></figure><p>Julian Gomez, who had just graduated from UC Berkeley, served as the Graphics Lab’s technical specialist. He left JPL in 1982 to pursue his doctorate with computer scientist Franklin C. Crow at Ohio State University. Here, he also collaborated with pioneering digital artist Charles “Chuck” Csuri, who was the lab director and head of the Computer Graphics Research Group.</p><p>Jim Blinn had recently earned his doctorate at the University of Utah, where he studied in the department founded by David Evans and Ivan Sutherland. Evans and Sutherland also founded a company (Evans &amp; Sutherland, or E&amp;S) that created digital simulations and produced the first commercial framebuffers.</p><p>Blinn’s advanced simulation software greatly contributed to the JPL Graphics Lab’s success. During his tenure at JPL, some of his early projects involved creating films simulating the Voyager I and II flybys of Jupiter and Saturn.<a href="https://computerhistory.org/blog/a-historic-pixel-art-exhibition/#note2">[2]</a> Blinn and his former mentor, Sutherland, would later both receive prestigious awards for their substantial contributions to the field of computer graphics.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*uXsxks443aS0urScYJpwDQ.jpeg" /></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*CwASws-w1kBVPmOkbBMwxA.jpeg" /><figcaption>Simulations by Jim Blinn of the Voyager I flybys of two of the moons of Jupiter: top: Io; bottom: Ganymede. Image courtesy of NASA/JPL.</figcaption></figure><p>Blinn and Em shared a symbiotic work relationship for more than a decade. Both would often work from 5 P.M. to 9 A.M., once the regular nine-to-fivers had gone home. Sitting in a cold room so the computers would not overheat, dressed for winter, it was almost like working on a space station. While Blinn was developing and improving the software, Em was using it to create art. His work from this period reflects the deep-space atmosphere in which he and Blinn were working.</p><p>While using the software to create art, Em would inevitably encounter glitches and would notify Blinn, who would fix them. The first artworks by Em, created with Blinn’s software on an E&amp;S framebuffer in Holzman’s Graphics Lab at JPL, were produced at the end of 1977. Blinn’s software had come a long way by September 1979, with the ability to create three-dimensional virtual worlds on the screen, including texture mapping and matrix transformations. Em was able to create images like Transjovian Pipeline, demonstrating what was technically possible with framebuffers at the time; an image that would become the poster child for digital art throughout the 1980s.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/700/1*IoJxWmCeyK7PFuqtYYLojw.jpeg" /><figcaption>Transjovian Pipeline, 1979, by David Em. A three-dimensional simulation of a world, and one of the artworks cycling on the Conrac monitors at the 1981 Framebuffer Show. This version was recovered from the original pixels on magnetic tapes with the assistance of the Computer History Museum and Jim Blinn in 2021. Image courtesy of David Em.</figcaption></figure><p>The team at NYIT that contributed artworks to the 1981 Framebuffer Show was directed by computer scientist Lance Williams, a researcher at the NYIT Computer Graphics Lab, which, like the JPL Graphics Lab, operated both as a research lab and a production facility. NYIT was founded in the 1950s by Alexander Schure, who envisioned creating feature-length animations. Comprised of both computer scientists and designers who collaborated to generate computer graphics, NYIT’s work environment was unique.</p><h3>Defying the Odds: Preparing the Show</h3><p>In June of 1981, just two months before the SIGGRAPH conference in Dallas, Holzman, Blinn, and Em met in the Graphics Lab to discuss the prospects of producing a framebuffer show. Blinn and Em proposed the project, which they had been contemplating for some time, and asked Holzman to allocate the lab’s resources. If they could pull it off, this would be the first time pixel images were displayed as intended in a public setting — that is, electronically, with direct feeds to high-resolution (at that time) monitors from framebuffers and a computer.</p><p>Holzman, who was passionate about the arts, agreed without hesitation — and the project quickly went into high gear. Part of the Graphics Lab team was at the same time preparing a film for the upcoming Voyager II flyby of Saturn (August 8, 1981), scheduled to take place around the same time as the conference.</p><p>Precisely how SIGGRAPH, then chaired by Thomas A. DeFanti, was brought on board remains unclear, but someone within the Graphics Lab made the necessary phone call to secure the showroom. James Seligman, with extensive production experience, was responsible for general communication between the team and external collaborators. He was also responsible for writing the press release.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*-iSLNt_ZIpVMpiH2B-m_Vg.jpeg" /><figcaption>The press release for the 1981 Framebuffer Show, listing the key players involved (<a href="https://history.siggraph.org/wp-content/uploads/2018/03/1981_info_pressRelease.jpg">https://history.siggraph.org/wp-content/uploads/2018/03/1981_info_pressRelease.jpg</a>).</figcaption></figure><p>But, would they be able to produce a show in less than two months, let alone secure the equipment? “It was pretty outrageous,” recalls Blinn, to even conceive of producing such a show. The monitors, framebuffers, and a computer could easily cost hundreds of thousands of dollars (in 1981 money!), and the sensitive equipment would need to be installed in the showroom (and later deinstalled).</p><p>Holzman preferred to remain minimally visible in the production of the 1981 Framebuffer Show to prevent it from appearing to be a NASA-sponsored project and to avoid drawing attention from the JPL hierarchy. However, he performed his magic and reached out to his hardware vendor contacts, including the vice president of Advanced Electronic Design (AED), Jerry Kennedy, who agreed to provide much of the hardware used in the exhibition.</p><p>In preparation for the show, Blinn told the NYIT contributors that they should submit their images on 9-track tapes (around 45–175 MB per tape). At the time, standard file formats, such as JPEG and TIFF, did not exist, nor did color spaces, let alone image compression.</p><h3>Making It Happen</h3><p>AED’s technical support assistant, Robin Radaczek, ensured that all the equipment was ready for the show on schedule, including six AED 512 8-bit framebuffers. It is unclear who arranged for six Conrac CRT (Cathode Ray Tube) monitors and, not least, a Digital Equipment Corporation (DEC) PDP-11 computer that drove the AED framebuffers and the Conrac monitors. The 1981 Framebuffer Show now had well over $200,000 (around $750,000 in 2026 money) in computing and display hardware at its disposal.</p><p>Julian Gomez had just returned to JPL after the spring quarter ended at Ohio State University when Holzman tasked him with preparing the installation and assembly of the show in Dallas. Blinn and Em had already decided which of their images to include and were awaiting NYIT’s contributions — once the artworks from the NYIT arrived, Blinn discovered he had to spend considerable time converting the files’ brightness and color settings to prepare them for the exhibition.</p><p>Gomez recalls that he developed the image display software in FORTRAN IV PLUS code in record time. He arranged the AEDs to cycle the image files across the six screens, displaying them in random order to provide a dynamic viewing experience.</p><p>The 1981 Framebuffer Show was scheduled to open at 10:00 A.M. on the Tuesday of the conference week, and Gomez planned to fly to Dallas Sunday evening with the tape of the images for the exhibition. He had spent the past six weeks prepping the final tape and writing the script for the software to be used at the show.</p><p>Blinn and Em had already left for Dallas, but Gomez stayed back at JPL because getting the master tape right was no trivial matter. It took hours to write and verify the files, and the magnetic tape technology of that era was incredibly slow. He had to postpone his trip three times before finally boarding an early Monday morning flight at 2:00 A.M. from LAX to Dallas. Gomez remembers how the tape — the only master tape — did not leave his hands for the entire trip. They were cutting it pretty close with only about 24 hours to go until showtime.</p><p>When Gomez arrived at the Dallas Convention Center on Monday morning, all the hardware was already in place, ready to be booted and the software installed. Everything went smoothly until the images got loaded. “They all looked like garbage,” Gomez said, recalling his horror at seeing corrupted images on the monitor.</p><p>Scrambling to fix the issue they called Eric Levy, who had stayed at the JPL Graphics Lab. Levy poked around and discovered that the RSX-11 Operating System (Real-Time System Executive) running on the Graphics Lab’s PDP-11 was inserting words into certain parts of the binary data, which appeared as an error code and corrupted the values of the raw image files. Thankfully, Levy’s discovery allowed Gomez and Blinn to modify the software to skip over the flawed data — and Hallelujah — the images appeared correctly.</p><p>Gomez and Blinn had spent all of Monday on this issue, and Gomez returned early Tuesday morning to finish the script for playing the images. He wrapped up just 20 minutes before the doors opened. But, rather than getting some well-deserved rest after nearly 60 hours of non-stop pre-production, Gomez was asked by AED’s Jerry Kennedy to do a presentation on his part in assembling the exhibition.</p><h3>Showtime</h3><p>At 10:00 A.M. on Tuesday, August 4, 1981, the doors opened to the exhibition in Room N 206 at the Dallas Convention Center; it ran through Friday, August 7th. Em recalls being surprised when he arrived early in the morning and found a long line of people waiting to get in to see the show. In addition to the press release, the only promotion for the 1981 Framebuffer Show was some signs James Seligman had hastily printed and put up in the hallways of the Convention Center.</p><p>When the audience entered the dimly lit room, they encountered the artworks displayed across six Conrac monitors raised to eye level. The PDP-11 computer and the AED framebuffers were concealed behind a curtain. The software Gomez had written enabled each of the six Conracs to cycle through the digital artworks by Blinn, Em, and NYIT every 5–10 minutes.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*1pEOLQMSFs5lJtfRaxOq6Q.jpeg" /><figcaption>Left image: the PDP-11 in the Graphics Lab at JPL, on which the mag tapes for the exhibition were generated. Right image: Julian Gomez (left) and Jim Blinn in the 1981 Framebuffer Show exhibition room, with the Conrac monitors in the foreground. Photo courtesy of David Em.</figcaption></figure><p>A full list of the images included in the exhibition remains incomplete. The master magnetic tape may still be recoverable; however, recovering data from mag tapes from this era has proven difficult. Gomez, who has since founded the Computer Graphics History Institute, is working on recovering the files to provide a complete record of the groundbreaking exhibition.<a href="https://computerhistory.org/blog/a-historic-pixel-art-exhibition/#note3">[3]</a></p><p>Based on the principals’ recollections, a partial reconstruction of the images in the exhibition is included below. Blinn’s images were contemporaneous with the Voyager I and II flybys of Saturn and Jupiter. They demonstrate his cutting-edge software, creating scientifically accurate texture mapping, transparency effects (e.g., the rings of Saturn), and cast shadows, as well as his work for Carl Sagan’s Cosmos television series.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*_tSqN7nBqoI0Ae4yR7XIxw.jpeg" /><figcaption>Simulation by Jim Blinn created in the Graphics Lab at JPL of Jupiter and its moon Io (1981). Image courtesy of NASA/JPL.</figcaption></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*JgnyfYMC6aYpXZTuXAk0lw.jpeg" /><figcaption>Simulation by Jim Blinn created in the Graphics Lab at JPL of Voyager II flyby of Saturn (1981). Image courtesy of NASA/JPL.</figcaption></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/500/1*Xypo82mGObRQEVcowfl0Gw.jpeg" /><figcaption>Simulation by Jim Blinn created in the Graphics Lab at JPL of Saturn and its moon Mimas (1981). Image courtesy of NASA/JPL.</figcaption></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/711/1*1xVGwkG0K95AYyr5F4RPXg.jpeg" /><figcaption>Simulation by Jim Blinn created in the Graphics Lab at JPL of DNA simulation for PBS Cosmos series (1981). Image © 2006 Druyan-Sagan Associates, Inc.</figcaption></figure><p>Em’s artwork reflected his growing involvement with navigable virtual worlds inspired by the deep-space environment in which he was immersed at JPL, and integrated surreal and dreamscape elements. While his images had previously been published and exhibited in print form, presenting them to the public in their original electronic context was a fundamentally different experience.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*hTf7vSmkOd-3UQ67fgceIw.jpeg" /><figcaption>Artwork by David Em © created at JPL using Jim Blinn’s software, Persepol (1980). Image courtesy of David Em.</figcaption></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/700/1*vpFAzeO4ZOzjmuVefH8uuw.jpeg" /><figcaption>Artwork by David Em © created at JPL using Jim Blinn’s software, Approach (1979). Courtesy of David Em.</figcaption></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*NdWjHkysvS7EYv6kD3QnhQ.jpeg" /><figcaption>Artwork by David Em © created at JPL using Jim Blinn’s software, Escher (1979). Image courtesy of David Em.</figcaption></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/700/1*lZfol_B9rb6bWh4HYDFDjg.jpeg" /><figcaption>Artwork by David Em © created at JPL using Jim Blinn’s software, But is it Art? (1981), an image created specifically for the exhibition, as Em repeatedly encountered people who questioned whether digital art was true art. Image courtesy of David Em.</figcaption></figure><p>Except for the artwork Swimmer (1981)<a href="https://computerhistory.org/blog/a-historic-pixel-art-exhibition/#note4">[4]</a> by Rebecca Allen, reconstructing a complete list of what was included from NYIT has not yet proven possible. Computer scientists Lance Williams and Dick Lundin may have contributed an 8-bit still image of their ant character from a film they were working on at NYIT, called The Works <a href="https://computerhistory.org/blog/a-historic-pixel-art-exhibition/#note5">[5]</a>; artist Paul Xander, who created 2D paintings using paint software written by Alvy Ray Smith, may have submitted The Desert Landscape; and computer scientists Fred Parke and Robert McDermott possibly included an image of the human body. Based on the known contributors from the press release and discussions with former NYIT employees, the images below are valid candidates.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/418/1*5UaoRf7ZdBJ55aGhq19Tyg.png" /><figcaption>Swimmer (1981) by Rebecca Allen. Image courtesy of New York Institute of Technology.</figcaption></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/442/1*RmNnoxHHqyuA81uqDpNXEA.png" /><figcaption>Robot Ant with Ipso (1981). Image courtesy of New York Institute of Technology.</figcaption></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/460/1*KlHxNAKOJnE6n_KK-57Daw.png" /><figcaption>The Desert Landscape (1975) by Paul Xander. Image courtesy of New York Institute of Technology.</figcaption></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/640/1*DOTurFhzGqhOdHy_dCWqyg.jpeg" /><figcaption>Faces (1981) by Fred Parke and Paul Heckbert. Image courtesy of New York Institute of Technology.</figcaption></figure><h3>Impact</h3><p>The historic 1981 Framebuffer Show fundamentally changed how digital images and art are displayed today; however, it would still be several years before fully digital exhibitions became mainstream in museums and other public settings, such as Times Square in NYC and the Sphere in Las Vegas. The 1981 Framebuffers Show is a prime example of how collaboration between visionaries can manifest something “outrageous.”</p><h3>Acknowledgements</h3><p>This account has been made possible through invaluable conversations with David Em, Jim Blinn, and Julian Gomez, which have helped ensure that the accounts of what transpired at JPL Graphics Lab and the 1981 Framebuffer Show are as accurate as possible. Alvy Ray Smith and Amber Denker were important sources in clarifying the history of the NYIT contributors’ involvement.</p><h3>Notes</h3><p>1.) Simulation film of NASA’s Voyager II’s encounter with Jupiter by Jim Blinn from 1978 <a href="https://youtu.be/o4xIJlEV8Kw?si=i40JclYq-MTIjKeE">https://youtu.be/o4xIJlEV8Kw?si=i40JclYq-MTIjKeE</a></p><p>2.) Jim Blinn’s presentation on how he created the planets for the simulations disseminated by JPL <a href="https://www.dropbox.com/scl/fi/zvmx5h03xjur6mq6iig5c/How-to-Make-a-Planet-Narration-Good-V3-640x480.mp4?rlkey=atatsxkaldf10req5dplp9v37&amp;e=2&amp;st=bj2v5g6b&amp;dl=0">https://www.dropbox.com/scl/fi/zvmx5h03xjur6mq6iig5c/How-to-Make-a-Planet-Narration-Good-V3-640x480.mp4?rlkey=atatsxkaldf10req5dplp9v37&amp;e=2&amp;st=bj2v5g6b&amp;dl=0</a></p><p>3.) Julian Gomez has founded the Computer Graphics History Institute to help preserve narratives like this about the 1981 Framebuffer Show <a href="https://www.computergraphicshistory.org/">https://www.computergraphicshistory.org/</a></p><p>4.) Rebecca Allen’s Swimmer <a href="https://history.siggraph.org/artwork/rebecca-allen-swimmer/">https://history.siggraph.org/artwork/rebecca-allen-swimmer/</a></p><p>5.) Lance Williams and Dick Lundin’s Robot Ant with Ipso <a href="https://history.siggraph.org/artwork/dick-lundin-lance-williams-robot-ant-with-ipso/">https://history.siggraph.org/artwork/dick-lundin-lance-williams-robot-ant-with-ipso/</a></p><p>Main image: Transjovian Pipeline, 1979, by David Em. A three-dimensional simulation of a world, and one of the artworks cycling on the Conrac monitors at the 1981 Framebuffer Show. This version was recovered from the original pixels on magnetic tapes with the assistance of the Computer History Museum and Jim Blinn in 2021. Image courtesy of David Em.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/50/0*ZI--J8zcsKJLTopI.png" /></figure><h3>About the Author</h3><p>Catharina E. Santasilia is a Danish-born anthropologist, archaeologist, and author. She earned her doctoral degree in anthropology from the University of California, Riverside, in 2019, where she also taught various courses. Currently, Santasilia works as an archivist, producer, and editorial associate for projects related to both ancient and digital art. Known for her curiosity and adventurous spirit, she effectively bridges the gap between scholarly research and public engagement through her writing and curation of collections.</p><p><em>Originally published at </em><a href="https://computerhistory.org/blog/hearing-tech-history/"><em>https://computerhistory.org</em></a><em> on April 10, 2026.</em></p><img src="https://medium.com/_/stat?event=post.clientViewed&referrerSource=full_rss&postId=c0faf5d464cf" width="1" height="1" alt=""><hr><p><a href="https://medium.com/chmcore/a-historic-pixel-art-exhibition-c0faf5d464cf">A Historic Pixel Art Exhibition</a> was originally published in <a href="https://medium.com/chmcore">Core+</a> on Medium, where people are continuing the conversation by highlighting and responding to this story.</p>]]></content:encoded>
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            <title><![CDATA[Celebrating Apple at 50]]></title>
            <link>https://medium.com/chmcore/celebrating-apple-at-50-0017b157249e?source=rss-de2302dabfe4------2</link>
            <guid isPermaLink="false">https://medium.com/p/0017b157249e</guid>
            <category><![CDATA[computing-history]]></category>
            <category><![CDATA[apple]]></category>
            <dc:creator><![CDATA[Computer History Museum]]></dc:creator>
            <pubDate>Thu, 19 Mar 2026 15:48:16 GMT</pubDate>
            <atom:updated>2026-03-19T15:49:11.271Z</atom:updated>
            <content:encoded><![CDATA[<p>By CHM Editorial</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*g6oovn8K3tD9qP1fAzgjlw.jpeg" /><figcaption>From left to right: David Pogue, Chris Espinosa, John Sculley, Avie Tevanian</figcaption></figure><h3>A Night of Stories and Surprises</h3><p>CHM was packed wall to wall on March 11, 2026, to celebrate Apple’s upcoming 50th anniversary. Inspired to write his new book, Apple: The First 50 Years, after hosting CHM’s Mac at 40 event two years ago, David Pogue returned to the stage to guide the audience through five decades of ideas, innovations, people, and passion.</p><p>Pogue opened with a reminder of how Apple has grown from its roots in a garage to the behemoth it is today. Nearly a third of the people on the planet — 2.5 billion — are carrying an Apple device at any given moment. The company ships 220 million iPhones a year, generates $1 million in revenue every 90 seconds, and is nearing a $4 trillion market cap.</p><p>But the night wasn’t about numbers. It was about the people behind them.</p><h3>Seeds of Apple</h3><p>Taking the audience back to the company’s profit engine, the Apple II, cofounder Steve Wozniak shared what Apple’s success meant to him in a video clip. It wasn’t the financial awards but rather earning the respect of fellow engineers for his ingenious design.</p><p>But that ingenuity may never have had a chance to change the world if Bill Fernandez (Apple’s first employee) had not connected his two friends named Steve when he was in high school.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2F_IgiS5Ex1gU%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3D_IgiS5Ex1gU&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2F_IgiS5Ex1gU%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/17d69c6fb8fe48dedd5a0c31a789d10d/href">https://medium.com/media/17d69c6fb8fe48dedd5a0c31a789d10d/href</a></iframe><h3>The Unknown Cofounder</h3><p>On April 1, 1976, Ronald Wayne mediated a disagreement between the two Steves and unintentionally convinced Steve Jobs that they needed to start a company in order to maintain control of their intellectual property. Wayne wrote up a partnership agreement then and there, becoming the third cofounder of Apple with 10% of the company so he could, according to Jobs, break a tie when the Steves disagreed. Twelve days later, Wayne backed out. At the event, he had a chance to explain why.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FlFennpHBV6I%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DlFennpHBV6I&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FlFennpHBV6I%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/0b71c351b07b849292e33bff1f6f44cf/href">https://medium.com/media/0b71c351b07b849292e33bff1f6f44cf/href</a></iframe><p>Jobs later mailed Wayne an unsolicited $800 check — “a cheap tip,” Wayne joked. He never sold his actual stake in the company, he says, despite the myth.</p><h3>Growing Up Apple</h3><p>A part of Apple for its entire 50 years, Chris Espinosa joined as a young teen. When his mother got tired of driving him to Homebrew Computer Club meetings, he hitched rides with Woz. Espinosa wrote the Apple II reference manual before he could legally drive. At a time when computers were strange, misunderstood machines, the Apple II debuted at the West Coast Computer Fair in 1977.</p><p>Board chair Mike Markkula coached the team to give the impression of a successful company. Espinosa remembers wearing new corduroy pants to stand in the slickest booth at the fair. Like an explosion, he said, people suddenly realized they could have computing power all to themselves.</p><p>But not everything went smoothly as the company grew. Espinosa recalled how adding a last-minute Apple II emulator to the Apple III caused it to have a tendency to overheat… badly.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FscDg_4nc_30%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DscDg_4nc_30&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FscDg_4nc_30%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/e0899b76a05e101643c751ea83db267b/href">https://medium.com/media/e0899b76a05e101643c751ea83db267b/href</a></iframe><p>Espinosa said Steve Jobs inspired fierce loyalty even when he made life difficult. Like when Jobs hired Espinosa to lead Mac publications while secretly planning to fire Jef Raskin, Espinosa’s mentor. Jobs had an ex officio role as cofounder at Apple before he latched onto the Mac project, said Espinosa. He was considered by many to be a pest, not cut out to run a company. When Jobs returned to Apple with the acquisition of NeXT, Espinosa expected more of the same. But it was different, he said. Jobs had learned.</p><h3>Leading Apple</h3><p>Former Apple CEO John Sculley recalled how Jobs had courted him when he was running Pepsi with the now famous, “Do you want to sell sugar water for the rest of your life, or come with me and change the world?”</p><p>Sculley wasn’t familiar with computers, but he had been an early Apple customer, having bought 550 Apple IIs to help his bottlers to send in their weekly sales figures. That status got him inside the Mac building. Andy Herzfeld had put a demo together that included dancing Pepsi cans, one of the first examples of computer animation that Sculley didn’t understand was a big deal at the time.</p><p>Sculley remembered Apple’s early culture and the sense of being on the cusp of something extraordinary, as well as the dramatic 1985 boardroom confrontation that resulted in Jobs’ removal from the Mac division.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FcuqsyHDDUXI%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DcuqsyHDDUXI&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FcuqsyHDDUXI%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/0d4d2889c3fe6df532c961673f837263/href">https://medium.com/media/0d4d2889c3fe6df532c961673f837263/href</a></iframe><p>Despite their disagreements, Sculley appreciated Jobs’s uncompromising standards.</p><p>There was an explosion of creativity under Sculley in the late ’80s and early ’90s, including Illustrator, PageMaker, Photoshop, and PowerPoint. He and his team also professionalized distribution and improved the Mac by making it expandable, and by 1992, it was the largest selling computer.</p><p>In the audience, Robert Brunner, Apple’s early design chief, who spearheaded the establishment of Apple’s world-class design studio, remembered the pressure of the early ʼ90s and the race to miniaturize and improve awkward portables. But despite his own accomplishments, Brunner says his legacy will always be “the guy who hired Jony Ive.”</p><h3>NeXT Comes Jobs</h3><p>Sculley was fired after 10 years amidst leadership disagreements about company direction. By 1996, there were 50 Mac models that no one could tell apart and 12 ad campaigns. There had been three CEOs, and the company was failing.</p><p>The Mac had never really had a modern operating system. To acquire one, Apple bought Jobs’ company NeXT and brought on him and brilliant engineers and leaders, including Avie Tevanian (software) and Jon Rubinstein (hardware).</p><p>Initially, they didn’t know what they were going to do, they just knew they needed new technology to compete with Windows 95 and other competitors. The NeXT technology worked, but it wasn’t what Mac developers wanted at the time. There was no other choice but to work it out. Tevanian describes the mixed reaction at Apple.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FzfQqOSgL4Ik%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DzfQqOSgL4Ik&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FzfQqOSgL4Ik%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/f2d1816565ee2db0552f8f8a4ffe63a5/href">https://medium.com/media/f2d1816565ee2db0552f8f8a4ffe63a5/href</a></iframe><p>Apple’s new leadership focused on just four products (desktop consumer and pro; portable consumer and pro), and one iconic ad campaign, Think Different, with the opening line, “Here’s to the crazy ones.” In perhaps the greatest turnaround in business history, a company that was six weeks from bankruptcy became profitable at $45 million one year later.</p><h3>Reinventing Apple</h3><p>Former Senior VP of Hardware Engineering Jon Rubinstein, who had come with Jobs from NeXT recalled (on video) the first executive staff meeting at Apple, where he and Avie Tevanian looked at each other and thought, “What are we getting ourselves into?” That turned out to be a reinvention, led by the iMac and the iPod.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FnjlPM--_Frk%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DnjlPM--_Frk&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FnjlPM--_Frk%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/5ea4cadad00a1ac0f98e7bb2f56ff36d/href">https://medium.com/media/5ea4cadad00a1ac0f98e7bb2f56ff36d/href</a></iframe><p>Beginning in 1998, the company frequently reinvented itself with new products: iMac, iPod, iPhone, iPad. When Jobs unveiled the iPhone in 2007, hardly anyone grasped that it would reshape the world. Espinosa said the first moment he realized its power was when he received a text message from his wife after the keynote that just said, “I want.”</p><p>Apple innovation didn’t end when Steve Jobs passed away in 2011. Tevanian noted that it simply shifted from blockbuster hardware to global software and services. The company succeeds by running faster and doing things better than the competition.</p><h3>What’s Never Changed</h3><p>The night closed with a final question: What threads tie Apple’s entire 50-year story together? Espinosa answered without hesitation: fear and pride. Apple was always terrified of being outpaced and always proud of doing things differently. Sculley added Jobs’s most consistent belief: “No compromises.”</p><p>The event concluded with a surprise — David Pogue performing a parody song he wrote about Apple fans to the tune of Pharrell Williams’ “Happy” that brought the audience to its feet.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FimuwYiMBql4%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DimuwYiMBql4&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FimuwYiMBql4%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/c5424292d83b0de85802641344dd8e44/href">https://medium.com/media/c5424292d83b0de85802641344dd8e44/href</a></iframe><h3>Watch the Full Conversation</h3><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FeCSNJgI2LFI%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DeCSNJgI2LFI&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FeCSNJgI2LFI%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/253b2bff238344ab68bb2a00ad61d686/href">https://medium.com/media/253b2bff238344ab68bb2a00ad61d686/href</a></iframe><p><em>Originally published at </em><a href="https://computerhistory.org/blog/celebrating-apple-at-50/">Celebrating Apple at 50 — CHM</a> <em>on March 19, 2026.</em></p><img src="https://medium.com/_/stat?event=post.clientViewed&referrerSource=full_rss&postId=0017b157249e" width="1" height="1" alt=""><hr><p><a href="https://medium.com/chmcore/celebrating-apple-at-50-0017b157249e">Celebrating Apple at 50</a> was originally published in <a href="https://medium.com/chmcore">Core+</a> on Medium, where people are continuing the conversation by highlighting and responding to this story.</p>]]></content:encoded>
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            <title><![CDATA[Apple History in Prototypes]]></title>
            <link>https://medium.com/chmcore/apple-history-in-prototypes-7ee636f1f1b7?source=rss-de2302dabfe4------2</link>
            <guid isPermaLink="false">https://medium.com/p/7ee636f1f1b7</guid>
            <category><![CDATA[apple]]></category>
            <category><![CDATA[apple-history]]></category>
            <category><![CDATA[apple-i]]></category>
            <category><![CDATA[computing-history]]></category>
            <dc:creator><![CDATA[Computer History Museum]]></dc:creator>
            <pubDate>Wed, 11 Mar 2026 21:07:43 GMT</pubDate>
            <atom:updated>2026-03-11T21:10:39.408Z</atom:updated>
            <content:encoded><![CDATA[<p>By Hansen Hsu</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/960/1*fnjEpxiQ6yp0wF4SqzwQKw.jpeg" /></figure><h3>Spotlight on Three Remarkable Eras</h3><p>This year Apple celebrates its 50th anniversary. Over the last 50 years, the iconic company has evolved through various phases: its founding in the garage; explosive growth with the Apple II; the debut of the Macintosh; the John Sculley, Michael Spindler, and Gil Amelio regimes; Steve Jobs’ return to save the company; the revolution of the iPhone and iPad; the current Tim Cook era.</p><p>At CHM, we’re celebrating Apple with an exhibit of rare prototypes from across Apple’s eras. Three are highlighted below.</p><h3>Apple I</h3><p>The Apple I, designed and built by Steve Wozniak as a hobby, started it all. After showing it off at the Homebrew Computer Club, Woz and Jobs were approached by Paul Terrell, the owner of the Byte Shop, the first chain of microcomputer retail stores in the Bay Area. Terrell’s order of 50 assembled Apple Is galvanized the Steves to start Apple. These first machines didn’t come with a case, so Jobs negotiated with local cabinet maker Charles Pfister Sr. and his son Chas, who knew Jobs as a teenager, to supply walnut wood cases to Apple I customers. On display is the original prototype case, made of birch and maple, designed and built by Chas.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*gf99hhXA2leQzH_ak_he6A.jpeg" /><figcaption>Prototype Apple I birch and maple wood case, designed and built by Charles “Chas” Pfister. While Chas signed his name on the prototype, Steve Jobs did not want it on the final version. Loan of Charles Pfister, #L001.2025.01.</figcaption></figure><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2Fk6Fvn5BTvDw%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3Dk6Fvn5BTvDw&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2Fk6Fvn5BTvDw%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/b1b5d2e7ba2e500a4bbd0f0e1c84bb89/href">https://medium.com/media/b1b5d2e7ba2e500a4bbd0f0e1c84bb89/href</a></iframe><h3>Macintosh</h3><p>Released January 24, 1984, the Macintosh brought the mouse-driven graphical user interface to a consumer desktop. While today all PCs work this way, this was revolutionary to most people in 1984.</p><p>On display at CHM are two notable Macintosh prototypes. One is a wire-wrapped board, made in June 1981 by Brian Howard and Daniel Kottke. Wire-wraps are hand-wired breadboards, assembled individually or in small batches at an early stage of development when engineers need to be able to change things quickly. Only when a design is locked down are printed circuit boards, which can’t easily be changed but allow for large production runs, made.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*FyNyojNkdOJyPHaVHOjm-Q.jpeg" /><figcaption>Macintosh wirewrap prototype #4, 1981. Gift of Andy Hertzfeld, 102638251.</figcaption></figure><p>The second prototype is a Macintosh in a transparent acrylic case, made circa December 1981, also by Howard and Kottke. This may have been the first prototype to show approximately what the final case design, designed by Jerry Manock and Terry Oyama, would look like. It would have been given to software developers, inside and outside Apple, to let them start writing apps for the Mac.</p><p>Notably, at this early stage, this prototype still uses an Apple II power supply and floppy disk drive. The decision to use Sony’s 3.5” floppy drive wouldn’t be made until 1983, and is associated with a <a href="https://www.folklore.org/Hide_Under_This_Desk.html">funny story</a> where Macintosh engineers had to ask a visitor from Sony Japan to hide from Steve Jobs in a closet!</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*tdTKC4THGicU8IwQhSmPtg.jpeg" /><figcaption>Macintosh Prototype in Acrylic Case, 1981. Gift of HSC Electronic Supply, <a href="https://www.computerhistory.org/collections/catalog/102717968/search/keyword:102717968/">102717968</a>.</figcaption></figure><h3>From Newton to iPhone</h3><p>After winning a power struggle with Steve Jobs in 1985, CEO John Sculley managed to turn Apple around and lead it into the Macintosh’s first golden age in the late 1980s, powered by the desktop publishing revolution. Sculley began to look to Apple’s future, towards mobile computing devices. Apple’s first mobile device was the Newton MessagePad, the first of a new category Sculley dubbed “personal digital assistants” or PDAs.</p><p>What may not be well-known is that the Newton began as a tablet-sized device, code-named “Cadillac.” But marketer Michael Tchao managed to convince Sculley that a smaller, cheaper, and less ambitious device was needed. Sculley green-lit the Newton “Junior” so long as it would fit in a man’s shirt pocket. Cadillac and Junior were developed in parallel for a time, but ultimately Cadillac was cancelled, and only Junior shipped. On display are prototypes of both products.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*f8jLEdfalLYdgxxZwQQTWg.jpeg" /><figcaption>Newton Cadillac Engineering Prototype, ca. 1994. Gift of Steve Capps, <a href="https://www.computerhistory.org/collections/catalog/102633650/search/keyword:102633650/">102633650</a>.</figcaption></figure><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*5VjdJRRzni9YxY5WIAH64w.jpeg" /><figcaption>Newton MessagePad Prototype, ca. 1995. Gift of Steve Capps, <a href="https://www.computerhistory.org/collections/catalog/102633644/search/keyword:102633644/">102633644</a>.</figcaption></figure><p>Famously, Newton’s launch was a disaster. Sculley had preannounced the Newton in January 1992, but its release was delayed until August 1993. Worse, the device’s promised handwriting recognition barely worked, famously lampooned in the comic strip Doonesbury. Combined with a disastrous June quarter and other factors, Sculley’s association with the Newton contributed to his firing by the Apple board. Subsequent updates would fix most of the Newton’s original issues, but it never became the wave of the future as Sculley had envisioned, and it would be killed by Steve Jobs upon his return to Apple in 1997.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*16lBHi6PAoktVPWJ0418OA.jpeg" /><figcaption>Doonesbury comic strip by Garry Trudeau, © Universal Press Syndicate, 500004918.</figcaption></figure><p>But Newton would plant the seeds of Apple’s future success in mobile computing. To make the Newton’s CPU, Apple co-created ARM, a joint venture with chip maker VLSI and British PC maker Acorn, with Apple owning a 43% stake. To keep Apple financially afloat in 1997, Apple sold most of its ARM shares. Thus, Apple’s ARM investment literally saved the company from bankruptcy. And when Apple began to make mobile devices again, like the iPod, iPhone, and iPad, it would use ARM chips.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*JibfQHE5Q1-fPaqUOrXWkg.jpeg" /><figcaption>iPod Prototype, ca. 2001. Gift of Shannon Wells, <a href="https://www.computerhistory.org/collections/catalog/102807216/">102807216</a>.</figcaption></figure><p>The iPhone transformed both Apple and the computer industry, making a reality the mobile-centric world that Sculley could only dream about in the 1990s. Today, Apple-designed ARM chips even power the Mac itself, enabling Macs to be both powerful yet energy efficient. What might have been Apple’s biggest failure may have sowed the seeds to its greatest success.</p><p>Stop by the Museum to see the exhibit through September 7, 2026, and check out an audio tour of highlights (in three languages!) <a href="https://apple50.atchm.org/">here</a>.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/50/0*7x092Z4QagDyF8fz.png" /></figure><h3>About the Author</h3><p>Hansen Hsu is a historian and sociologist of technology, and curator of the CHM Software History Center. He works at the intersection of the histories of personal computing, graphical user interfaces, object-oriented programming, and software engineering.</p><p><em>Originally published at </em><a href="https://computerhistory.org/blog/apple-history-in-prototypes/">Apple History in Prototypes — CHM</a><em> on March 11, 2026.</em></p><img src="https://medium.com/_/stat?event=post.clientViewed&referrerSource=full_rss&postId=7ee636f1f1b7" width="1" height="1" alt=""><hr><p><a href="https://medium.com/chmcore/apple-history-in-prototypes-7ee636f1f1b7">Apple History in Prototypes</a> was originally published in <a href="https://medium.com/chmcore">Core+</a> on Medium, where people are continuing the conversation by highlighting and responding to this story.</p>]]></content:encoded>
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            <title><![CDATA[In Memoriam: Sir Antony Hoare (1934–2026)]]></title>
            <link>https://medium.com/chmcore/in-memoriam-sir-antony-hoare-1934-2026-903059aec33d?source=rss-de2302dabfe4------2</link>
            <guid isPermaLink="false">https://medium.com/p/903059aec33d</guid>
            <category><![CDATA[computing-history]]></category>
            <dc:creator><![CDATA[Computer History Museum]]></dc:creator>
            <pubDate>Wed, 11 Mar 2026 17:00:10 GMT</pubDate>
            <atom:updated>2026-03-11T21:08:54.283Z</atom:updated>
            <content:encoded><![CDATA[<p>By Dag Spicer</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*jYaICgAsAQAip0IrHKlFvA.png" /><figcaption>Photograph by Rama, Wikimedia Commons, <a href="https://en.wikipedia.org/wiki/Tony_Hoare#/media/File:Sir_Tony_Hoare_IMG_5125.jpg">https://en.wikipedia.org/wiki/Tony_Hoare#/media/File:Sir_Tony_Hoare_IMG_5125.jpg</a></figcaption></figure><h3>2006 CHM Fellow</h3><p>The Computer History Museum (CHM) mourns the passing of Sir Antony Hoare, a 2006 CHM Fellow and a foundational architect of modern computing, who died on March 5, 2026, at the age of 92. Tony, as he was known to friends and colleagues, was more than a scientist; he was a philosopher of the machine, dedicated to the idea that software should be as reliable and elegant as a mathematical proof.</p><p>Born in Colombo, Sri Lanka, and educated at Oxford in the Classics, Hoare’s unconventional path into computing gifted him with a unique perspective on language and logic. In 1959, while studying at Moscow State University, he developed Quicksort, an algorithm that remains the industry standard for efficiency nearly seven decades later. It was an early harbinger of his career-long pursuit: finding the most elegant solution to the most complex problems.</p><h3>A Legacy of Rigor and Logic</h3><blockquote>There are two ways of constructing a software design: One way is to make it so simple that there are obviously no deficiencies, and the other way is to make it so complicated that there are no obvious deficiencies.— <em>Sir Antony Hoare</em></blockquote><p>Sir Tony’s contributions to the field are seminal. In 1969, he introduced Hoare Logic, a formal system of rules for verifying the correctness of computer programs. At a time when software was often a “black box” of trial and error, Hoare provided the mathematical scaffolding to prove that a program would actually do what it was intended to do. This work laid the groundwork for the field of formal methods and high-integrity systems.</p><p>Hoare’s development of Communicating Sequential Processes (CSP) later revolutionized our understanding of concurrency. By treating independent processes as entities that communicate through synchronized exchanges, he provided a rigorous framework for the parallel computing world we inhabit today. His seminal 1980 Turing Award lecture, “The Emperor’s Old Clothes,” remains required reading for any student of system design, famously warning against the “traps” of needless complexity.</p><h3>A Curator’s Perspective</h3><p>While many will remember Sir Tony for the complex logic that bears his name, those in the computer science community often reflect on his humility. He famously referred to his invention of the “null reference” as his “billion-dollar mistake” — a testament to his rare ability to critique his own monumental contributions with grace and wit.</p><p>I am reminded of a story from his early days in the 1960s at Elliott Brothers. He had been trying to explain the concept of a “recursive” subroutine to his manager. After an hour of Tony’s brilliant, dense mathematical explanation, the manager looked at him, completely baffled, and said, “Tony, I don’t care if the program talks to itself, as long as it doesn’t do it on company time.” Tony often shared this story with a laugh, a reminder that even the greatest minds in computing once struggled to translate the future into the language of the present.</p><p>The Museum extends its deepest condolences to his wife, Jill, and their family. Sir Tony Hoare did not just teach us how to code; he taught us how to think. His absence leaves a profound void in the global computing community, but his logic remains embedded in the very foundations of the digital world.</p><h3>Learn More</h3><p>CHM Oral History of Sir Antony Hoare: <a href="https://www.computerhistory.org/collections/catalog/102658017/">https://www.computerhistory.org/collections/catalog/102658017/</a></p><p>Shustek, L. J., “An Interview with C.A.R. Hoare,” Communications of the ACM, March 2009, vol. 52, no. 3.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/50/0*ydKg4hyYQachwXRB.png" /></figure><h3>About the Author</h3><p>Dag Spicer is CHM’s senior curator and is responsible for creating the intellectual frameworks and interpretive schema of the Museum’s various programs and exhibitions. He also leads the Museum’s strategic direction relating to its collection of computer artifacts, films, documents, software and ephemera — the largest collection of computers and related materials in the world.</p><p><em>Originally published at </em><a href="https://computerhistory.org/blog/in-memoriam-sir-antony-hoare-1934-2026/">In Memoriam: Sir Antony Hoare (1934–2026) — CHM</a><em> on March 11, 2026.</em></p><img src="https://medium.com/_/stat?event=post.clientViewed&referrerSource=full_rss&postId=903059aec33d" width="1" height="1" alt=""><hr><p><a href="https://medium.com/chmcore/in-memoriam-sir-antony-hoare-1934-2026-903059aec33d">In Memoriam: Sir Antony Hoare (1934–2026)</a> was originally published in <a href="https://medium.com/chmcore">Core+</a> on Medium, where people are continuing the conversation by highlighting and responding to this story.</p>]]></content:encoded>
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            <title><![CDATA[Dating in a Digital World]]></title>
            <link>https://medium.com/chmcore/dating-in-a-digital-world-7594a5f8ef15?source=rss-de2302dabfe4------2</link>
            <guid isPermaLink="false">https://medium.com/p/7594a5f8ef15</guid>
            <category><![CDATA[dating-app]]></category>
            <category><![CDATA[computer-dating]]></category>
            <category><![CDATA[computing-history]]></category>
            <dc:creator><![CDATA[Computer History Museum]]></dc:creator>
            <pubDate>Fri, 13 Feb 2026 16:55:37 GMT</pubDate>
            <atom:updated>2026-02-13T16:56:43.404Z</atom:updated>
            <content:encoded><![CDATA[<p>By CHM Editorial</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*XuNbuLrrFx0xpboMY4Ez2g.jpeg" /></figure><blockquote>Anything that could create more love is a positive thing. <em>— Gary Kremen</em></blockquote><p>Have you ever used a dating app? If so, you’re not alone. Hundreds of millions of people use dating apps daily. Just in time for Valentine’s Day, CHM Live featured a panel of online dating experts from different eras, including Cofounder of Operation Match Jeffrey Tarr, Founder of Match.com Gary Kremen, and online dating consultant Steve Dean. The panel was moderated by Hanna Kozlowska, author of an upcoming book on the topic.</p><h3>Punch Card Connecting</h3><p>“We were two males in college who were very unlucky at dating,” explains Jeff Tarr, cofounder of Operation Match. It was 1965, and he was a 19-year-old undergraduate at Harvard. With money he’d won on a quiz show and a knowledge of IBM machines gained in a summer job, he and a friend launched a new endeavor. Offered at elite colleges in New England, Operation Match was originally a questionnaire with 75 questions that hopeful students could submit to have an “all-knowing” computer match them with a compatible date for $3.</p><p>Advertised by newspapers that would receive 10% of the take, Tarr received 7,800 responses. He and his partner paid to have them punched onto cards and rented service on an IBM 1401 during cheap off-hours to have them processed. Participants received 6 “ideal dates” and Operation Match was up and running. Improving the questionnaire and expanding across the country, the second version was wildly successful.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FwuBjVaRfyiQ%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DwuBjVaRfyiQ&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FwuBjVaRfyiQ%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/f573820006a2c413276e15e47cee5e4b/href">https://medium.com/media/f573820006a2c413276e15e47cee5e4b/href</a></iframe><p>Operation Match worked on a simplistic basis, Tarr noted, nowhere near today’s dating apps. Of the 150 questions, they only effectively used 10 in the computer sort. But, there is plenty of anecdotal evidence that it worked — married couples still approach Tarr to thank him for connecting them.</p><h3>Internet Introductions</h3><p>When Gary Kremen was in his late 20s and a graduate student at Stanford’s business school, he was looking for dates through personal ads and 900 numbers without success. Good at computers and intrigued by how personal ads drove revenue for newspapers, he devised Match.com, the first and biggest online dating service.</p><p>The first incarnation, in 1993–1994, was based on email since few people had web browsers at the time. When the internet arrived, Match servers would go into overdrive during lunchtime because people could only access the web at work. At that time, more women were entering the workforce, people were marrying later, and everyone seemed eager to find a match efficiently. When Kremen realized there was a disconnect regarding profile photos — men wanted them, women didn’t — he decided to dig deeper.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2F8agL82g7Wf8%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3D8agL82g7Wf8&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2F8agL82g7Wf8%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/a50f8635ebfdcd53ae43a997fefe0c02/href">https://medium.com/media/a50f8635ebfdcd53ae43a997fefe0c02/href</a></iframe><p>Talking to women customers and bringing women into the company made Match.com better, with security features like blocking. Back then, the market was so huge that Kremen wasn’t worried about customer acquisition, even though he might lose two customers if the service succeeded so well that a couple dropped off when they committed to each other.</p><h3>App Attraction</h3><p>Steve Dean says that today’s dating apps have made the cost of rejection very low, and users don’t usually leave an app permanently. Relationships often end after all. Lifetime user value is calculated not just on the initial period when a user joins the app but rather over the course of years. Often, a new user will burn out in first couple months because they’re using many apps at the same time, but after that wears off, they’re back on again. People clearly want to believe the apps work, but do they?</p><p>Dean believes dating apps have solved the problem of compatibility — delivering attractive matches — but a longer-term commitment that probably has a certain element of randomness is more difficult to deliver. Mobile devices and the ability to make profiles quickly has streamlined the industry. In 2012, Tinder collapsed everything down to four taps and a user could make a profile and get a match in seconds. That was unheard of at the time — the platforms required extensive questionnaires, and an eHarmony profile took 45 minutes to complete, for example.</p><p>But lately, dating app fatigue seems to be setting in. Dean is clear on the cause — the monopolistic Match Group and their addictive products.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FGh7ZZGlkclo%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DGh7ZZGlkclo&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FGh7ZZGlkclo%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/388889868408e844e26214c9834c9add/href">https://medium.com/media/388889868408e844e26214c9834c9add/href</a></iframe><p>Match Group owns Tinder, Hinge, Match, Plenty of Fish, and countless other dating apps. Dean treats himself as a guinea pig, joining all of them and more so that he can see what people are experiencing. That sometimes involves messages coming in during the middle of the night trying to get him to engage. He takes screenshots of those and puts them in a folder he calls “Notification Hell.”</p><p>AI is now playing a role in the industry. Dean notes that it is now possible to be engaging only with an AI on a dating app, further reducing the human authenticity that people crave. On the positive side, some apps are adding AI that can help a user create a better profile or join in on a thread to help them flirt. As Gary points out, AI is like any other new tool or platform, and it can be used for good and bad. The tech is still in its infancy as far as helping to solve the business side of dating apps. Once it succeeds, we’ll see connection like we never have before.</p><p>So, hold on a little longer and you just might find that special someone!</p><p>[Main image: From left to right, Hanna Kozlowska, Gary Kremen, Steve Dean.]</p><h3>Watch the Full Conversation</h3><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2Fm6OtfCp3YY4%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3Dm6OtfCp3YY4&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2Fm6OtfCp3YY4%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/f256dfe79ca5485a2d91e6eec3e83616/href">https://medium.com/media/f256dfe79ca5485a2d91e6eec3e83616/href</a></iframe><img src="https://medium.com/_/stat?event=post.clientViewed&referrerSource=full_rss&postId=7594a5f8ef15" width="1" height="1" alt=""><hr><p><a href="https://medium.com/chmcore/dating-in-a-digital-world-7594a5f8ef15">Dating in a Digital World</a> was originally published in <a href="https://medium.com/chmcore">Core+</a> on Medium, where people are continuing the conversation by highlighting and responding to this story.</p>]]></content:encoded>
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            <title><![CDATA[Read Me]]></title>
            <link>https://medium.com/chmcore/read-me-904dc1ef9126?source=rss-de2302dabfe4------2</link>
            <guid isPermaLink="false">https://medium.com/p/904dc1ef9126</guid>
            <category><![CDATA[computing-history]]></category>
            <dc:creator><![CDATA[Computer History Museum]]></dc:creator>
            <pubDate>Wed, 11 Feb 2026 19:35:28 GMT</pubDate>
            <atom:updated>2026-02-11T19:36:26.085Z</atom:updated>
            <content:encoded><![CDATA[<p>By CHM Editorial</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*O0CfD0_c3a1QpOmj4gBrcg.jpeg" /></figure><h3>Exploring the Books of the Computing Revolution</h3><p>It may be hard to imagine in our current digital age, but printed books were once considered an innovative (and dangerous!) technology. And, for decades, books have helped people to understand the quickly evolving revolution in computing.</p><p>On January 20, 2026, author and UC Santa Barbara history professor W. Patrick McCray was on stage at CHM Live to share his experiences writing ReadMe: A Bookish History of Computing from Electronic Brains to Everything Machines (MIT Press, 2025). The fireside chat was moderated by David C. Brock, CHM’s Robert and Bette Finnigan Fellow.</p><h4>Prologue</h4><p>McCray began to think about his project during the pandemic, when he thought he might be able to write a book about books so that he could read at home and avoid traveling to archives. Those circumstances made him consider how every book has its own origin story and history, and McCray became just as interested in exploring the authors and their writing processes, their relationships with their publishers, and the cultural context of the books he was writing about as he was their content.</p><p>For ReadMe, McCray wanted to explore the ways technology was presented to the public. He limited his selection to nonfiction books that represented a range of different functions. Some, like Alvin Toffler’s Future Shock (1970), were bestsellers by any measure, some were technical textbooks, and others popularized computing for a general audience. He also had to choose his historical timeframe.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FoqKwcTSmmco%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DoqKwcTSmmco&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FoqKwcTSmmco%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/fb2c9c3642f0ff7dc2e918cc08807579/href">https://medium.com/media/fb2c9c3642f0ff7dc2e918cc08807579/href</a></iframe><p>Records really do matter, says McCray, noting that it’s critical that people donate their papers to a repository. He shared what he found in some of those archives.</p><h4>Chapter 1: Giant Brains</h4><p>McCray first discussed Giant Brains: Or, Machines That Think, published in 1949. The author, Edmund C. Berkeley, had worked in the booming insurance industry from the 1930s to ’50s, a sector rich in data and among the major adopters of digital and electronic computers — called “giant brains” at the time.</p><p>Berkeley wanted to explain what computers were and how they worked and hired a writing coach to ensure that the average person could understand his book. Alarmed by post-WWII geopolitical tensions and the threat of nuclear war, Berkeley used the book to warn that computers were powerful tools that could be dangerous if not developed with robust ethics and morals.</p><h4>Chapter 2: Power vs. Reason</h4><p>MIT has a robust archival collection for Joseph Weizenbaum and his book Computer Power and Human Reason (1976), reported McCray. Weizenbaum was a computer scientist at MIT in the early 1960s famous for writing the program for the ELIZA chatbot that functioned as a Rogerian psychotherapist. Many users felt that ELIZA was interacting with them on an emotional level. Horrified to see how people imbued the program with empathy, Weizenbaum became concerned about what computers and computer scientists should and shouldn’t do. His book was a critique of the profession, and perhaps of himself.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FETQt_7mwpgU%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DETQt_7mwpgU&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FETQt_7mwpgU%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/413c543a6efe8b51f33c684e5127524b/href">https://medium.com/media/413c543a6efe8b51f33c684e5127524b/href</a></iframe><h4>Chapter 3: Manifesto</h4><p>Ted Nelson’s 1974 Computer Lib/Dream Machines combined two books back-to-back, assembled and self-published by the author himself. It was a political manifesto that promoted computers as tools for personal liberation, freedom, and democracy. Nelson also predicted that people would someday have computers in their pockets and considered how they would interact with hypermedia and multimedia, like images, sound, and text. Reprinted in 1987, after the PC revolution had not unfolded the way he’d hoped, Nelson lamented that ubiquitous computers could oppress people from everywhere.</p><h4>Chapter 4: Fonts and Text</h4><p>Don Knuth, author of the influential The Art of Computer Programming series, was sitting in front of the CHM stage. When reading Knuth’s lectures about typography and typesetting, McCray recognized a shared appreciation for printing, fonts, books, and history. He felt that Knuth’s book on creating digital typesetting, The TeXbook (1986), had to be included in his own book somehow. Fortunately, many of the papers related to the book are at Stanford and many have been digitized.</p><h4>Chapter 5: Radical Textbook</h4><p>Carver Mead and Lynn Conway’s Introduction to VLSI Systems, published in 1979, was a textbook, but also a catalyst for the formation of a community. McCray found robust archival materials, for Mead at Caltech and in Conway’s online archive to explore how a textbook about how chips were designed actually had radical agenda.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2F0cvjRvYSKYk%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3D0cvjRvYSKYk&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2F0cvjRvYSKYk%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/851586cb84ff829b10962daaae97ac71/href">https://medium.com/media/851586cb84ff829b10962daaae97ac71/href</a></iframe><p>Later, in the ’80s and ’90s, Conway told an interviewer that she could see her enduring influence at engineering schools, where chip designs reflected the principles laid out in her and Mead’s textbook.</p><h4>Chapter 6: Newspapers and Newsletters</h4><p>In addition to books, McCray also included newspapers and newsletters as important media for communicating about the computing revolution. In her Release 1.0 electronics newsletter, business analyst Esther Dyson explained the new world of cyberspace to the average reader in the 1980s and ’90s and became a regular talk show guest.</p><p>McCray included the San Jose Mercury News in his book in order to discuss the evolution of the modern tech journalist. Today, there are hundreds writing about some aspect of the tech industry, but the tech journalist was only beginning to emerge in the late ’70s and early ‘80s.</p><p>People like Evelyn Richards, a Mercury business reporter with traditional journalism training, and freelancer Michael Malone, who had once written promotional copy for HP, began writing about Silicon Valley at a time when mainstream publications were still learning what the place was all about. They helped bring attention and understanding to it, covering both the good and the bad.</p><h4>Chapter 7: Readers</h4><p>The enthusiastic audience shared their favorite books about computers and computing, with the clear winner being Soul of a New Machine by Tracy Kidder, published in 1981. They also reported what books featured in McCray’s ReadMe they had read. See the results below.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*w0TkJEBgrb7Yg4h5pYql8A.png" /></figure><h3>Epilogue</h3><p>McCray says that one of the most interesting aspects of writing his book was seeing the way that ideas like “author,” “writer,” “publisher,” and “bookstore” were dynamic over the time period he covered. How students learn about books, purchase them and consume them today is very different than in past decades. And introducing AI into the mix is making things even more dynamic. What does it mean when computers become authors? That remains to be seen.</p><p>In the meantime, be assured that Patrick McCray wrote every word of his book himself.</p><h3>Watch the Full Conversation</h3><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FreeVfmw4sbI%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DreeVfmw4sbI&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FreeVfmw4sbI%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/b3bc29f9b8f3e4d9b649cf1443db2e11/href">https://medium.com/media/b3bc29f9b8f3e4d9b649cf1443db2e11/href</a></iframe><img src="https://medium.com/_/stat?event=post.clientViewed&referrerSource=full_rss&postId=904dc1ef9126" width="1" height="1" alt=""><hr><p><a href="https://medium.com/chmcore/read-me-904dc1ef9126">Read Me</a> was originally published in <a href="https://medium.com/chmcore">Core+</a> on Medium, where people are continuing the conversation by highlighting and responding to this story.</p>]]></content:encoded>
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            <title><![CDATA[Generative Music with the Muse]]></title>
            <link>https://medium.com/chmcore/generative-music-with-the-muse-0d2fe03ab633?source=rss-de2302dabfe4------2</link>
            <guid isPermaLink="false">https://medium.com/p/0d2fe03ab633</guid>
            <category><![CDATA[computing-history]]></category>
            <category><![CDATA[vintage-synthesizer]]></category>
            <category><![CDATA[electronic-music]]></category>
            <dc:creator><![CDATA[Computer History Museum]]></dc:creator>
            <pubDate>Fri, 23 Jan 2026 16:58:56 GMT</pubDate>
            <atom:updated>2026-01-23T17:00:08.609Z</atom:updated>
            <content:encoded><![CDATA[<p>By Jeff Cardello</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*JCZEvU7o8CPzkjREvQ_sVQ.jpeg" /></figure><h3>The forgotten sequencer that brought algorithmic composition to the home</h3><p>Strolling around the Computer History Museum, there are exhibits that are immediately recognizable. All we need is a glimpse of the Altair 8800 or Apple I, and we just… know. We walk over and stand in front of these pieces, instinctively lowering our voices and giving a quiet nod to anyone nearby. Like noticing the chisel marks on a marble statue or the brushstrokes on an oil painting, we’re struck by the realization that what we’re seeing is the result of human imagination and ingenuity. What was once abstract and almost mythical is there right in front of us.</p><p>However, there are also items on display at the Computer History Museum whose significance isn’t immediately apparent. Take the Triadex Muse. You might mistake this wedge of metal, switches, and wood panels for an obsolete piece of stereo equipment or a Cold War-era intercom.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/624/1*kx5iI8iUDzIaOUXJPbmfgQ.jpeg" /><figcaption>The Triadex Muse on display at the Computer History Museum. Photo by Michael Hicks, November 3, 2013. (Source: <a href="https://commons.wikimedia.org/wiki/File:Triadex_Muse_synthesizer_(1972),_Computer_History_Museum.jpg">Wikimedia Commons</a>)</figcaption></figure><p>While it looks like something you’d find on some forgotten warehouse shelf, the Triadex Muse is an important piece of electronic music history. Developed by Edward Fredkin and Marvin Minsky at MIT in 1969, and commercially released in the early 1970s, it was the first algorithm-based sequencer/synthesizer intended for home consumers. It’s estimated that there were only 280–300 produced, making it a rare piece of gear.</p><p>You won’t find a friendly and familiar set of piano keys. The only controls are an orderly series of sliders. Its industrial design has more in common with that of a home appliance than a musical instrument. Like some sort of mystical radio receiver, beckoning users to adjust its controls until they land on some strange and alien wavelength.</p><h3>Playing Music Through Binary Logic</h3><p>The beauty of the Triadex Muse is in its simplicity. There’s no memory, no CPU, and no firmware. Just integrated circuits and electricity. Unlike the 1959 IBM 7090 mainframe computer, which was fed programming instructions via paper punch cards in coaxing out such party hits like Frère Jacques on the 1962 album <a href="https://www.computerhistory.org/collections/catalog/102651537/">Music from Mathematics</a>, the only user input here is positioning sliders and flipping a couple switches.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/1024/1*JDtipVAUTYwM32Z2_hcQNw.png" /><figcaption>The Triadex Muse is a simple combination of electronics, lacking RAM, ROM, or software. (Source: <a href="https://archive.org/details/triadex_TRIADEX_MUSE_USER_MANUAL/mode/2up">Internet Archive)</a></figcaption></figure><p>If you were to randomly move the sliders to different positions and fire up the Triadex Muse, you’d likely hear the chirp of a square wave melody from its internal speaker and see a vertical band of blue and green lights twinkling in time. You might think that the Triadex Muse is like a modern step sequencer or drum machine. Orderly and predictable. This is 1972. Forget it.</p><p>You wouldn’t be wrong that the blinking lights correspond to a beat. At each tick of the Muse’s internal clock, this single column of lights shows the complete state of zeroes and ones. The Muse is essentially a 40 x 8 matrix, with zeroes and ones evaluated at each “tick” of its internal clock, triggering sounds, and with each state potentially changing what happens next.</p><p>While anyone with a background in computer science would know what these lamps represent, the average home consumer would have no idea. These glittering lights further add to its sense of mystery. Although you do get some control over the Muse’s output, you can’t play it like a regular instrument. Even the owner’s manual admits that, “The Muse isn’t a music box.” Depending on how you set the sliders, it’s unlikely you’re going to come up with a tune you can hum along with while you wash the dishes.</p><iframe src="https://cdn.embedly.com/widgets/media.html?src=https%3A%2F%2Fwww.youtube.com%2Fembed%2FIbUVd_mNiQM%3Ffeature%3Doembed&amp;display_name=YouTube&amp;url=https%3A%2F%2Fwww.youtube.com%2Fwatch%3Fv%3DIbUVd_mNiQM&amp;image=https%3A%2F%2Fi.ytimg.com%2Fvi%2FIbUVd_mNiQM%2Fhqdefault.jpg&amp;type=text%2Fhtml&amp;schema=youtube" width="854" height="480" frameborder="0" scrolling="no"><a href="https://medium.com/media/003082a6517c19602e979273fbc34815/href">https://medium.com/media/003082a6517c19602e979273fbc34815/href</a></iframe><h3>Making Melodies</h3><p>While the Muse may sound like a robotic run-on sentence, it speaks in the familiar language of musical intervals.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/600/1*O9IV-lFJWYRmjyfJtsc0lA.png" /><figcaption>Closeup of the Triadex Muse showing intervals. Photo by Mark Richards.</figcaption></figure><p>The INTERVAL block has four sliders that select notes from the major scale. The positions of A, B, and C determine the pitch, while D adds an octave. There are no flatted thirds or minor scales. You can’t play the blues. Though you might want to if you once owned the Triadex Muse and look up how much they’re currently going for — $$$.</p><p>The four INTERVAL switches, like much of the Muse, are deceptively straightforward. You might flip several to the same row and think you’ll hear a chord. Once again the Muse doesn’t follow modern conventions.</p><p>The Muse isn’t polyphonic. There is no harmony or overtones. This is binary arithmetic. Each interval is a weighted four-digit binary number. When summed they generate a 4-bit number that determines a new pitch. Music from mathematics… indeed.</p><p>The Muse’s intervals are triggered when the positions that they’re set to get a one bit from either the C or B section.</p><p>If you were to stare at the blue lights marked C ½ to C6 long enough, along with your friends asking you if you were feeling okay, you’d notice that they follow a set pattern. And if you knew how to count in binary (and let’s face it we know there are some of you out there), you’d see that the lamps C1, C2, C4, and C8 form a four-bit counter, cycling from 1 (0001) to 15 (1111) in a continuous loop. C ½ is simply the clock itself, a square wave that turns on and off at a rate linked to the tempo. C3 and C6 form a separate two-bit counter that increments every three cycles. By setting groups of threes against fours adds variety to the sequence.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/624/1*7eyMwsm3AXFz6-iEz0MoSg.png" /><figcaption>Counting up from C8, we see 0100, which is four in binary. (Source: JavaScript Triadex Muse <a href="https://till.com/muse/barbican/">emulator</a> built by <a href="https://till.com/">Donald Tillman</a>)</figcaption></figure><p>In most instances, if you set the INTERVALS only to C positions, you’d get repeating patterns of tones about as musically exciting as the 1978 memory game Simon (no offense to Simon, which you can also see on display at the CHM).</p><h3>Pseudo-Random Sequencing</h3><p>The B region is where the Muse becomes more than a repeating blooper of bleeps, but a generator of pseudo-random chaos. You might observe the flickering green lights occupying B1 — B31, and just when you’ve identified a pattern, the sequence feeds back and morphs into something new.</p><p>To understand what’s happening, first you need to know what the four THEME sliders actually do. If you think that flipping these will give you a familiar musical preset like rock, jazz, or a rumba, the Muse once again betrays you.</p><p>Each THEME slider is technically a “tap.” A tap is like a tiny beacon, monitoring the binary state of a specific point in the C or B region, and sending that off to an XNOR logic gate.</p><p>I know. This sounds complex. But understanding the B register is like finding the answer to a riddle. Once you see it, it’s oh-so-obvious.</p><p>At every click, the XNOR (Exclusive NOR) logic gate makes a decision based on what it receives from the taps. If the gate receives an even number of ones (including all zeroes), it sends a one to B1. If the number of ones is odd, it sends a zero to B1. In its default state, B1 — B31 will be a band of green.</p><p>Every decision the Muse makes lurches forward, sometimes syncing up as the same conditions persist, and then suddenly shifting when the inputs change. B1 — B31 is what is known as a Linear Shift Register, an ever-evolving bucket brigade of bits, where a new zero or one is handed to the top, while the bottom bit falls out.</p><figure><img alt="" src="https://cdn-images-1.medium.com/max/624/1*UXOnsD-67l4i8HHukY6HLA.png" /><figcaption>The 31-bit B register creates an almost unending variety of variations and patterns. (Source: <a href="http://till.com/">Donald Tillman’s</a> JavaScript based Triadex Muse <a href="https://till.com/muse/barbican/">emulator</a>)</figcaption></figure><h3>A Predecessor to Modern Generative Music</h3><p>The Triadex Muse is a dead-end in the history of electronic music. While one could daisy chain it to other Muses, it used a proprietary I/O. There are no control voltages you could patch into modular synthesizers. And MIDI was a decade away. Its entire ecosystem was The Triadex Muse itself, an external speaker, and if the march of blue and green squares wasn’t enough visual stimulation, you could also buy a light unit with Gaussian-like blurs of psychedelic colors flowing with the beat.</p><p>Like DNA from extinct species whose fragments persist in modern organisms, the Muse’s influence lives on in algorithmic composition.</p><p>In a 2001 interview, Sean Booth of Autechre, pioneers of generative electronic music said about their process that, “There’s absolutely nothing random about what we do. There might be a lot of number crunching going on, but there’s nothing random in there.”</p><p>This is exactly what the Muse was doing in 1972.</p><p>Marvin Minsky, the co-creator of the Muse, said in his 1981 paper “<a href="https://web.mit.edu/6.034/www/6.s966/Minsky-MusicMindMeaning.pdf">Music, Mind, and Meaning</a>” that the challenge of composing music is that, “Whatever the intent, control is required or novelty will turn to nonsense.” This philosophy is hardwired into the Muse.</p><p>The melodies of the Muse could sound familiar. Or even strange. But its output still sounds like music, with underlying rules and logic that our brains detect as patterns, even though the Muse makes it almost impossible to predict what it will play next.</p><p><strong>Main image: Triadex Muse, 1972. Computer History Museum, XD254.81. Gift of Ed Fredkin. Photo by Mark Richards.</strong></p><figure><img alt="" src="https://cdn-images-1.medium.com/max/50/0*W6R7j5WwNBeIwt5Q.png" /></figure><h3>About the Author</h3><p>Jeff Cardello is a freelance writer specializing in software, technology, and design. His first computer was an Apple IIe, and he has fond memories of playing Wizardry, the chatter of dial-up modems, and typing `10 PRINT “HELLO”` and `20 GOTO 10` on any computer unfortunate enough to be left unattended. You can find him on LinkedIn where he shares most of his writing, and things he has found cool or inspiring.</p><p><em>Originally published at </em><a href="https://computerhistory.org/blog/hearing-tech-history/"><em>https://computerhistory.org</em></a><em> on January 23, 2026.</em></p><img src="https://medium.com/_/stat?event=post.clientViewed&referrerSource=full_rss&postId=0d2fe03ab633" width="1" height="1" alt=""><hr><p><a href="https://medium.com/chmcore/generative-music-with-the-muse-0d2fe03ab633">Generative Music with the Muse</a> was originally published in <a href="https://medium.com/chmcore">Core+</a> on Medium, where people are continuing the conversation by highlighting and responding to this story.</p>]]></content:encoded>
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