In many parts of our world today, group communication centers on visual materials built with âpresentation software,â often crafted by a speaker him or herself. As a result, meetings now generally depend on the use of personal computers, presentation software in the guises of product or service and display by digital projectors or flat-screens.
A humorous sample PowerPoint presentation supplied with the very first version in 1987. This clip was created with PowerPoint 1.0 for Mac running in a Mac Plus emulator.
So central have these visual materials become that the intended functioning of digital files, programs, computers, and peripherals has become an almost necessary condition for public communication. Choice of presentation software has even become a mark of generational and other identities, as in whether one uses Facebook or Snapchat. Millennials and Generation Z choose Google Slides or Prezi. Everyone else uses PowerPoint, its mirror-twin by Apple called Keynote, or, for political expression and/or economic necessity, LibreOffice. Membership in a highly technical community can be signified by using the typesetting program LaTeX to build equation-heavy slides.
It is PowerPoint, nevertheless, that has become the âKleenexâ or âScotch Tapeâ of presentation software. A âPowerPointâ has come to commonly mean any presentation created with software. Microsoft rightly boasts that there are currently 1.2 billion copies of PowerPoint at large in the world today: One copy of PowerPoint for every seven people. In any given month, approximately 200 million of these copies are actively used. PowerPoint is simply the dominant presentation software on the planet.1
It may come as a surprise, then, to learn that PowerPoint was not the first presentation program. Rather, there were several programs for personal computers that performed similarly to PowerPoint in many respects, which appeared starting in 1982âfully five years before PowerPointâs debut. PowerPointâs ubiquity is not the result of a first-mover advantage.2
Further, many of PowerPointâs most familiar characteristicsâthe central motif of a slide containing text and graphics, bulleted lists, the slide show, the slide sorter, and even showy animated transitions between slidesâwere not absolute novelties when PowerPoint appeared. These elements had been introduced in one form or another in earlier presentation software.

Here, the principal developers of PowerPointâDennis Austin and Tom Rudkinâdescribe the structure of the source code defining slides. Austin and Rudkin worked closely with the productâs architect, Bob Gaskins. This document is in a collection of materials donated to the 91×ÔĹÄ by Dennis Austin.
From 1982 through 1987, software makers introduced roughly a dozen programs for several different personal computers that allowed users to create visual materials for public presentations as a series of âslidesâ containing text and graphic elements. Frequently, these slides were printed on paper for incorporation into a photocopied report and transferred to a set of transparencies for use with an overhead projector. Other presentation programs allowed slides to be output as a sequence of 35mm photographic slides for use with a slide projector, a videotape of a series of slide images, or a digital file of screen-images for computer monitors. Makers and users called these programs âpresentation software,â and just as commonly âbusiness graphics software.â âBusinessâ here is significant, I think.3
Early presentation software was most commonly used to create overhead presentations. In this clip, Dennis Austinâa principal developer of PowerPointâdemonstrates the use of overhead projectors and presentations.
The six years from 1982 through 1987 saw the emergence of presentation software (including PowerPoint), with multiple makers introducing competing programs offering many similar capabilities and idioms. Why did multiple, independent software creators develop presentation software for personal computers at just this moment?
I believe that an analytical framework that I developed with historian Christophe LĂŠcuyer to understand episodes in the history of solid-state electronics can also help us to unpack this very different case from software history. Our framework consists of three âcontextual logicsâ that we argue shaped the emergence of the planar transistor, the silicon microchip, the simultaneous-invention of silicon-gate MOS technology, and, as Christophe and Takahiro Ueyama recently show, the history of blue light-emitting diodes (LEDs).4
In their 2013 article, âThe Logics of Materials Innovation,â Christophe and Takahiro describe these logics beautifully:
The implication seems straightforward: People from similar backgrounds, in similar organizations, facing a common, structured set of contextual logics, will do similarâbut not identicalâthings. But can these logics that help make sense of the history of semiconductor electronics, a technology deeply about materials, also give insights into the history of the ne plus ultra of the digitalâsoftware itself? I think it can. Competitive logic, Market logic, and Material logic: Letâs consider them in that order, and see what they can mean for the âprehistoryâ of PowerPoint.
Competitive logic centered on software makers. In the first half of the 1980s, makers of presentation software were typically connected to companies. There were, of course, makers of non-commercial software of various stripesâhobbyist, open source, libre and the likeâbut they do not appear to have been a factor in early presentation software. Rather, the makers of presentation software were what I call âintegrated software manufacturers,â âsoftware publishers,â and âauthor houses.â Sometimes the boundaries between these maker-types are blurry, but I think the categories are useful.
Integrated software manufacturers, ranging from cottage firms to public companies, wrote code, manufactured it mainly on magnetic media, wrote and printed technical documentation and guides, and distributed it in shrink-wrapped boxes. For integrated software manufacturers of this era, think of Microsoft, Lotus Development, and MicroPro International." Software publishers" did everything that the integrated manufacturers did, except write the code. Rather, they entered into contracts on a royalty basis with those who did write programs. Software publishers ran the gamut from stand-alone companies that only produced software written by others, to firms that published a mix of programs written internally and externally, and also to computer makers like Apple, who published software written by others under their own label as well as selling their own programs. Code authors ranged from individual sole proprietorships to âauthor shops,â partnerships between two or more programmers in an LLP or a small company.
The origins of Microsoft, perhaps the best-known integrated software manufacturer.
These author shops, publishers, and integrated manufacturers were, by 1982, competing in a growing market for personal computer application software: Spreadsheets, word processors, databases and âbusiness graphicsâ programs that often used data from spreadsheets to generate line-graphs, pie-charts, bar-graphs, and other standard plots used in business, science, and engineering. This battle for market share in applications for personal computers was the âcompetitive logicâ for presentation softwareâs emergence.5
âMarket logicâ centered on the intended users of software, and, in the case of presentation software, focused to the communication practices of white-collar workers in the United States (and, perhaps, elsewhere), particularly âmanagersâ and âexecutives.â Contemporary commentators noted that personal-computer âbusinessâ software like spreadsheets represented a turn in âoffice automation,â the opening of a new phase in which software users would expand beyond specialists and secretaries to managers and executives. Personal computers with new software would be in the offices of Mahogany Row in addition to the accounting department and the typing pool.
For example, in September 1982, John Unger Zussman, a columnist for InfoWorld, noted: ââŚthe market is changing. An examination of the changing word-processor marketplace can tell us a lot about the maturation of microcomputers and give us a clue to the role of micros in the office of the future. âThereâs an expanding concept of reality in the modern office,â says Gary Smith, NCRâs director of marketing. Software oriented toward managers, such as spreadsheet and slide-show programs and electronic mail, has increased the demand for distributed data processing. It is now legitimate for a computer to appear on a managerâs deskâor a secretaryâs. The personal workstation, says Smith, is becoming âthe major focus of white-collar productivity.â This was not always the case. In the past, computers were the province of the data-processing departmentâŚand, besides, managers wouldnât be caught dead typing at a keyboardâŚword processing became a stepping-stone into the automated officeâŚthe introduction of microcomputers into the office of the future seems to be more a process of infiltration than one of direct assault.â6
In this 1979 commercial, Xerox presented just this vision of the office of the future.
In a 1984 article in the Proceedings of the IEEE titled âA New Direction in Personal Computer Software,â MIT Sloan School professor Hoo-Min Toong, with his postdoc Amar Gupta, identified the crux of the market logic to which presentation software was a response: The time that executives and managers spent in meetings. They write: âTop managers are noted to spend four-fifths of their time attending meetingsâdelivering or receiving presentations and reports, communicating, and gathering information for subsequent meetings. Meetings are the most prominent, time consuming element of an executiveâs job.â They continue: âAt present, business personal computers only represent information in numeric form, in text, and in simple charts and graphs. A crucial missing component is the ability to present and manipulate visual, pictorial dataâŚA new layerâŚwill bridge the gap from the present positionâŚto supporting business communications with sophisticated images and color.â7

Toong and Guptaâs diagram of the proportion of an âexecutiveâsâ time spent in meetings. Š 1984 IEEE. Reprinted, with permission, from Proceedings of the IEEE.
Toong and Gupta then discuss a newly released example of such âpresentation graphics software,â VCN ExecuVision, offered by the book publisher Prentice-Hall. VCN ExecuVision, which ran on the IBM PC, cost $400 but also required libraries of images and icons, that is, âclip art,â at $90 per floppy disk. Users could create âslide showsâ of multiple âslidesâ that the user could craft with text, clip art, and geometric shapes, as well as pie, bar, and line graphs, with the completed slide show either printed or displayed on the PC monitor.
The idiom of the slide was directly adapted from the world of 35mm photographic slides. âSeeing a single slide is one thing,â Toong and Gupta write, âseeing an aggregate of slides is another. VCN ExecuVision supports slide shows in which the transition from one slide to another can be controlled either manually (pressing a key causes display of the next slide) or automatically⌠More significant is the support of animation techniques which give an illusion of seeing a running movie rather than a slide showâŚVCN ExecuVision brings sophisticated graphical capabilities to the realm of personal computers thus vastly expanding the horizons of personal computer applications in all four domains â office, home, science, and education.â Continuing their celebration of ExecuVision, Toong and Gupta illustrated their journal article with three full-color pages of ExecuVision slides, replete with images having the unmistakable aesthetic of clip art. Presentation software and clip art may have been born together.

Sample slides from VCN ExecuVision. Š 1984 IEEE. Reprinted, with permission, from Proceedings of the IEEE.
Evidently, ExecuVision was the creation of Toong himselfâin a Cambridge, Massachusetts author shop called Visual Communication Network Inc.âbefore the program had been sold or licensed to Prentice Hall. Toong filed articles of incorporation for the firm in October 1983, with his brother and a former MIT industrial liaison as the other directors. His brother was listed as the president and a Sloan School building was the firmâs address. Toongâs connection to ExecuVision is not mentioned in the article.8

Lotusâ announcement of Executive Briefing System. Courtesy of the Kapor Archive.
Toongâs ExecuVision was, in late 1983, a new entrant into the presentation software market that two new integrated software manufacturers, located in neighborhoods on opposing sides of the MIT campus, had already enjoined. On one side was Mitch Kaporâs startup, Lotus Development. Kapor created his new firm on a windfall from two programs he had written that were published by Personal Software, Inc., later renamed VisiCorp. VisiCorp was also the publisher of the breakthrough spreadsheet program VisiCalc, written in Cambridge by Software Arts Inc., the âauthor shopâ of Dan Bricklin and Bob Frankston.
Mitch Kapor had written a statistical analysis and data graphing program for the Apple II called TinyTROLL, which he sold through a partnership with his friend and then MIT finance PhD student Eric Rosenfeld who had suggested the program to Kapor. The partnership was called Micro Finance Systems, and Kapor was approached VisiCorp to adapt TinyTROLL to work with data imported from VisiCalc. Kapor soon delivered VisiPlot and VisiTrend, programs that took VisiCalc spreadsheet data and generated pie, bar, and line graphs from them, as well as performed various finance-relevant statistical functions on the data. Kapor and Rosenfeldâs Micro Finance Systems received hundreds of thousands of dollars in royalties for VisiPlot and VisiTrend before VisiCorp bought them outright for $1.2 million. With his share in the windfall, Kapor set up an integrated software manufacturer of his own, Lotus Development, and, in 1982, the firm released its first product, Executive Briefing System, for the Apple II. Todd Agulnick, a 14-year-old high school student, had been hired by Kapor and wrote the BASIC code for Executive Briefing System under his direction.9
Lotusâ $200 Executive Briefing System was centered on the color video display of the Apple II. In brief, a number of programs for charting and graphing like VisiPlot offered the âBSAVEâ command. Instead of routing data to immediately render an image on the video display, BSAVE sent the very same data to a stored file. In this way, a âscreen shotâ could be rendered on the video display at a later time, shared with others, archived for future use, etc. Lotusâ Executive Briefing System treated BSAVEâd filesâthese screen shotsâas âslidesâ that could be modified and then displayed on the Apple IIâs video display as a âslide showâ for a âpresentation.â Executive Briefing System users could edit slides of charts and plots by adding text and/or clip art of lines, geometric shapes, or âornamentalâ motifs. Slides were arranged in slide shows, and saved to floppy disk. While the program allowed a slide show to be printedâas a paper report or for transparencies for overhead presentationâit focused on slide shows for the video display. A variety of animated âtransitionsâ between slides were available, such as fades, wipes, and spinning-into-view.10
An early Executive Briefing System demonstration. This clip was created by running an image of the demonstration disk in an Apple II emulator.
David Solomontâs Business and Professional Software Inc., another integrated software manufacturer developing products for the Apple II, was located at 143 Binney Street just a 25-minute walk across the MIT campusâand past Hoo-Min Toongâs officeâfrom Kaporâs Lotus Development office at 180 Franklin Street. Like Kapor, Solomontâs firm had earlier developed a plotting and charting program for the Apple II to work with VisiCalc spreadsheets. Solomont struck a deal with Apple to license the plotting program, which was sold by Apple under the companyâs brand as âApple Business Graphics.â Soon thereafter, arriving on the market about the same time as Lotusâ Executive Briefing System, came Solomontâs âScreen Directorâ program in 1982.11
A 2015 91×ÔĹÄ oral history interview with David Solomont.
Screen Director, made for the then-new Apple III computer, fully embraced treating a computer running Screen Director like a 35mm slide projector. Users could organize BSAVEâd image files from programs like VisiPlot and Apple Business Graphics into various âslide traysâ for presentation on the video display. While Screen Director did not allow for the editing of existing image slides, it did provide for the creation of text slides and for a limited set of animated transitions between slides. Screen Director even shipped with the standard two-button wired controller for slide projectors, but modified to plug into the Apple III for controlling Screen Director slide shows.12

A 1982 print advertisement for Business and Professional Softwareâs Screen Director program.
So far I have described a meaning for âcompetitive logicâ and âmarket logicâ in the case of presentation software, and some early programs from 1982 through 1984. But what of âmaterial logic?â Material logic here includes personal computers themselves, specifically personal computers with graphics capabilities that were expanding in the early 1980s. The computersâ physical performativity, their material agency, constituted a resource, medium, and constraint for software makers and users. Existing programs widely used on these computers, like spreadsheets and plotting programs, were themselves a critical part of the material logic. Software, like hardware, has an unavoidable materiality. At the most abstract, a computer program can be considered to be a specific pattern. In practice, every instance of a program is a pattern in something material, including the body of an author.
Finally, the material logic for presentation software included operating systems centered on the graphical user interface, or GUI. This style of computing had been pioneered at Xerox PARC in the late 1970s, most famously on the Xerox Alto computer. The Alto inspired other efforts to bring the GUI into personal computing during the first half of the 1980s: Appleâs Lisa and Macintosh computers, Microsoftâs Windows software, and VisiCorpâs VisiOn software to name but a few.13
This material logic was especially important in the creation of PowerPoint. In 1983, two Apple managers, Rob Campbell and Taylor Pohlman, left the firm and created a new integrated software manufacturer, Forethought Inc. Simply put, they left Apple to bring a Xerox Alto like GUI operating system to the IBM PC. By 1986, however, Forethought Inc. had a change of plans. This storyâof Forethoughtâs creation of PowerPointâand other stories about what PowerPoint and its competitors can tell us about software history, will be the subjects of upcoming essays by me on the @91×ÔĹÄ blog.
For more information about the development of PowerPoint, please see our .