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Interdata
Interdata
Interdata
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Interdata's offices and manufacturing facility in Oceanport, New Jersey (here seen in 2022), consisted of four interconnected buildings that were constructed from the 1960s through 1983.[1]

Key Information

Interdata, Inc., was a computer company, founded in 1966 by a former Electronic Associates engineer, Daniel Sinnott, and was based in Oceanport, New Jersey. The company produced a line of 16- and 32-bit minicomputers that were loosely based on the IBM 360 instruction set architecture but at a cheaper price.[2] In 1974, it produced one of the first 32-bit minicomputers,[3] the Interdata 7/32. The company then used the parallel processing approach, which uses more than one computer processor simultaneously to perform work on a problem. This helped in making real-time computing a reality.[4][5]

Some real-time applications Interdata computers were used for included: Core Protection Calculator, used in some later Combustion Engineering designed nuclear power plants; lottery systems manufactured by GTech; the NexRad weather radar system. Many companies used them for internal high speed laboratory data capture, such as United Technologies Research Center in East Hartford, Connecticut wind tunnel, General Electric R&D in Schenectady, New York, and Perkin-Elmer in Connecticut (which later acquired Interdata).

The 16-bit computers had several operating systems, such as the Basic Operating System (BOSS),[6] Disk Operating System (DOS),[6][7] Real Time Operating System (RTOS),[6] and OS/16.[8] The 32-bit computers had OS/32. The assembly language could generate series independent object code. Later, as with Gould, SEL, Modcomp and other real time competitors, they offered a 32-bit time sharing system called MTM (Multi Terminal Monitor).

Acquisitions

[edit]

In 1973, Interdata was purchased by Perkin-Elmer Corporation,[9] a Connecticut-based producer of scientific instruments for $63.6 million.[4] Interdata was already making $19 million in annual sales but this merger made Perkin-Elmer's annual sales rise to over $200 million.[4] Interdata then became the basis for Perkin-Elmer's Data Systems Group.[10] In 1985, the computing division of Perkin-Elmer was spun off as Concurrent Computer Corporation.[11]

List of products

[edit]
Interdata 7/32
  • Interdata Model 1 – 1970[12]
  • Interdata Model 3 – 1967[13][14]
  • Interdata 4 (autoload, floating point)
  • Interdata 5 (list processing, microcoded automatic I/O channel)
  • Interdata 70 (1971), 74 (1973), 80 (1971), 85 (Writable Control Store, 1973)[12]
  • Interdata 50, 55 (Communications systems)
  • Interdata 5/16, 6/16, 7/16 (1974)[12]
  • Interdata 8/16, 8/16e (double precision floating point, extended memory)
  • Interdata RD-800 and RD-850 – 1975[12]
  • Interdata 7/32 – 1974[12]
  • Interdata 8/32 – 1975[12]
  • Perkin-Elmer 3205, 3210, 3220, 3230, 3240, 3250, 3280

A simulator is available: http://simh.trailing-edge.com/interdata.html

References

[edit]
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Interdata

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Interdata, Inc. was an American computer company founded in 1966 in Oceanport, New Jersey, that specialized in the design and production of 16- and 32-bit minicomputers as an early competitor to firms like Digital Equipment Corporation. Acquired by Perkin-Elmer Corporation in 1973 for $63.6 million, it continued operations under Perkin-Elmer, contributing to advancements in computing technology for scientific and industrial applications until the division's sale in 1985, with notable ties to Perkin-Elmer's work in scientific instruments. Established by Daniel Sinnott, a former engineer from Electronic Associates, Interdata quickly emerged as a key player in the burgeoning minicomputer market during the late 1960s and early 1970s. The company focused on producing reliable, high-performance systems such as the Interdata Model 70 and later the groundbreaking Interdata 7/32, one of the first 32-bit minicomputers introduced in 1974 following the acquisition. These machines were marketed to a range of customers, including major corporations like General Electric and Ford Motor Company, as well as government agencies, with over 2,000 units delivered valued at more than $50 million by the mid-1970s. Interdata's innovations emphasized compatibility and expandability, positioning it as a viable alternative to dominant players in the industry. Under Perkin-Elmer's ownership, Interdata's computing division integrated with the parent company's expertise in optical and electronic instruments, enhancing applications in scientific research and real-time processing. This synergy supported Perkin-Elmer's broader portfolio in scientific and space technology. By 1985, amid shifting market dynamics in computing, Perkin-Elmer sold the division, which evolved into Concurrent Computer Corporation, marking the end of the Interdata brand but leaving a legacy in minicomputer architecture and scientific computing.

History

Founding and Early Development

Interdata, Inc. was founded in 1966 in Oceanport, New Jersey, by a group of engineers including Daniel Sinnott, who served as a key figure in its establishment. The company was established with the primary goal of entering the burgeoning minicomputer market, positioning itself as a competitor to industry leaders such as Digital Equipment Corporation (DEC). This initiative was driven by the recognition of growing demand for compact, affordable computing systems in scientific, industrial, and research applications during the mid-1960s. From its inception, Interdata began establishing its operations, leveraging the founders' expertise from prior roles in the electronics and computing sectors. The company prioritized organizational setup, establishing its headquarters and initial facilities in Oceanport to support core operations. These efforts laid the foundation for the company's entry into product development, marking a transition toward market engagement in subsequent years.

Growth and Market Competition

Following its founding in 1966, Interdata, Inc. pursued aggressive expansion in the late 1960s, aligning with the burgeoning minicomputer market that saw rapid industry-wide growth from $65 million in sales in 1967 to $210 million by 1970. By 1969, the company had grown sufficiently to file a registration statement with the U.S. Securities and Exchange Commission for a public offering of 300,000 common shares, aiming to raise approximately $3.75 million to support scaling operations. This capital infusion was earmarked for key growth areas, including $800,000 for manufacturing and testing equipment, $200,000 for research and development expansion, $200,000 for marketing staff and new sales offices, and $900,000 to bolster inventories of parts and materials, reflecting a strategic push to increase production capacity and market presence amid rising demand for affordable computing solutions. Interdata's market entry strategies emphasized targeting scientific and industrial applications, positioning its products—loosely based on the IBM System/360 instruction set—as cost-effective alternatives to more expensive mainframes, appealing to organizations seeking modular, lower-cost systems for specialized tasks without the overhead of larger installations. In the competitive landscape of the minicomputer sector, Interdata directly rivaled established players like Digital Equipment Corporation (DEC), which dominated with its PDP series, by offering competitively priced 16-bit systems that undercut DEC's offerings while providing comparable performance for industrial and scientific users. For instance, while DEC's PDP-8 retailed around $18,000 in the mid-1960s and set industry benchmarks, Interdata's emphasis on IBM-compatible architecture enabled it to capture niche markets through superior compatibility and pricing advantages, contributing to intense rivalries that drove overall market innovation and price reductions during 1968–1972. Other competitors, such as Data General with its Nova line introduced in 1969, further intensified dynamics, but Interdata differentiated itself by prioritizing embedded applications over general-purpose computing. Notable early milestones included the 1969 public stock offering, which not only provided essential funding but also marked Interdata's entry into broader U.S. capital markets, facilitating partnerships with underwriters like Gregory & Sons and expanding its visibility in the computing sector. Although specific sales contracts from this period remain sparsely documented, the company's growth trajectory positioned it as a key supplier in the U.S. minicomputer ecosystem.

Acquisition by Perkin-Elmer

In March 1974, Perkin-Elmer Corporation, a manufacturer of scientific instruments, announced an agreement in principle to acquire Interdata, Inc., marking its entry into the minicomputer market. The deal was motivated by Perkin-Elmer's strategic interest in expanding its capabilities in data processing and computing technology to complement its existing work in analytical instruments for chemical and physical research. Under the terms, Perkin-Elmer would issue 0.8 shares of its common stock for each share of Interdata common stock, with approximately 2,030,055 Interdata shares outstanding, valuing the transaction at roughly $63.6 million based on Perkin-Elmer's closing stock price of $39 per share on the announcement date. The acquisition was completed in August 1974 through a stock exchange that absorbed Interdata into Perkin-Elmer's corporate structure. Key figures in the negotiations included Interdata's leadership, with the company's founders playing central roles in facilitating the deal. Post-acquisition, immediate organizational changes preserved continuity by retaining Daniel Sinnott as president and Arthur Furman as vice president for planning and advanced development, ensuring seamless integration of Interdata's 700 employees and operations into Perkin-Elmer's broader organization based in Norwalk, Connecticut. In the short term, the acquisition allowed Interdata to maintain its independent branding for products, such as the introduction of the 32-bit Interdata 7/32 minicomputer later in 1974 under Perkin-Elmer's ownership, while leveraging the parent company's resources for growth. This transition supported ongoing sales to major customers like General Electric and Ford Motor Company, with Interdata's prior deliveries exceeding $50 million in value.

Products and Technology

16-bit Minicomputer Line

Interdata's 16-bit minicomputer line began with the introduction of early models such as the Model 1 and Model 3 in the late 1960s, marking the company's entry into the competitive minicomputer market as an alternative to established players like Digital Equipment Corporation. These systems were designed with a processor architecture featuring a 16-bit word length, 16-bit fixed-point operands, and 16/32-bit instructions, emphasizing compatibility with IBM 360-style programming to ease adoption by existing mainframe users. The development process involved leveraging discrete transistor logic and core memory technology prevalent at the time, with hardware components including up to 16 accumulators and 15 index registers for efficient computation. Software support included basic 1- and 2-pass assemblers and rudimentary operating systems that served as precursors to later offerings like OS/16, enabling real-time operations and multi-tasking coordination tailored for emerging scientific applications. Technical specifications highlighted the line's suitability for scientific computing, with memory capacities ranging from a minimum of 2,048 words to a maximum of 32,768 words (up to 64 KB) using core memory with a 1.0-microsecond cycle time and optional parity checking. I/O capabilities were robust, supporting 8/16-bit word sizes, optional direct memory access (DMA) channels for up to 500,000 words per second, and external interrupt levels scalable from 2 to 256, allowing integration with peripherals like magnetic tape drives (up to 20K characters per second), punched card readers (200 cards per minute), and A/D converters for data acquisition. Hardware features such as standard byte manipulation, optional multiply/divide, and floating-point operations further enhanced performance for numerical tasks, with add times varying by model, such as 3.9 microseconds for full-word operations on the Model 4. These attributes positioned the systems for use in laboratory instrumentation and process control, where cost-effective, programmable solutions were needed over hardwired alternatives. In terms of market performance during Interdata's independent years, the 16-bit line achieved moderate success, particularly in research and industrial settings. For instance, the Model 3 saw its first delivery in July 1970, with 30 units installed by May 1971, while the related Model 4 (a compact 16-bit variant introduced in August 1968) reached 408 installations by the same date, reflecting growing demand for affordable systems priced around $10,000 to $15,000 for basic configurations with 4K to 8K words of memory and a Teletype terminal. Applications spanned data logging in scientific experiments, industrial process monitoring, and real-time control in sectors like astronomy, where systems like the Model 70 (delivered in 1972) supported precise telescope operations with accuracies of 1-2 arc seconds. Overall, these models contributed to Interdata's reputation for innovative, OEM-friendly hardware, helping the company generate early revenue in a market projected to grow 30-50% annually.

32-bit Minicomputer Innovations

Following the acquisition of Interdata by Perkin-Elmer in 1973, the company introduced the Model 7/32 in 1974 as one of the first commercially available 32-bit minicomputers, marking a significant advancement in minicomputer technology by extending addressing and processing capabilities beyond the limitations of 16-bit systems. The 7/32 featured a full 32-bit architecture with 32 general-purpose registers, each 32 bits wide and organized into two stacks of 16 for efficient context switching, enabling direct memory addressing up to 1 megabyte while supporting a physical memory maximum of 1 megabyte using core memory modules. This design addressed key engineering challenges in scaling from 16-bit predecessors by incorporating upward compatibility through a halfword mode that allowed seamless execution of 16-bit instructions alongside 32-bit code, preventing performance loss during migration and reducing software redevelopment costs. The architecture of the 7/32 included an optional Memory Access Controller (MAC) that provided hardware support for virtual memory through segmentation, relocation, and protection mechanisms, utilizing 16 registers to map 20-bit logical addresses to physical ones and dividing programs into up to 16 segments ranging from 256 bytes to 64 kilobytes. Performance metrics highlighted its efficiency, with memory cycle times of 750 to 1000 nanoseconds (0.75 to 1 microsecond) for 32-kilobyte modules and instruction execution times starting at 1 microsecond for basic loads, scaling up to 100 microseconds for complex operations like division, which established it as a high-speed option for scientific and real-time applications without the bottlenecks of earlier 16-bit designs. Innovations in the instruction set design comprised 242 instructions across formats supporting 16-, 32-, and 48-bit lengths, encompassing arithmetic and logical operations, list processing, floating-point computations (via optional hardware), cyclic redundancy checking, and bit/byte manipulations, with features like double indexing and 86 extended branch mnemonics to enhance programming flexibility and efficiency. Building on the 7/32, the Model 8/32 was launched in 1975 as an enhanced 32-bit minicomputer, incorporating four-way interleaved memory and dual 64-bit instruction lookahead stacks to achieve an effective cycle time of 300 nanoseconds, a substantial improvement over the 7/32's 750-nanosecond memory cycles while using the same core memory technology. Its virtual memory support mirrored the 7/32's MAC but emphasized 20-bit address translation for up to 1 megabyte of physical memory, expandable in 128-kilobyte increments, allowing for robust segmentation and protection in multitasking environments. The instruction set retained compatibility with the 7/32 while adding optimizations for fixed- and floating-point operations, with execution times as low as 1.25 microseconds for adds and 2.5 microseconds for double-precision multiplies, demonstrating successful scaling that maintained or improved performance in high-throughput scenarios. A notable innovation in both models was their early compatibility with Unix-like systems, as Sixth Edition Unix was ported to the 7/32 in 1976-1977 at the University of Wollongong, making it one of the first non-PDP platforms to run Unix and facilitating broader adoption in academic and research settings through adaptations that leveraged the 32-bit instruction set for efficient system calls and process management. Similarly, Unix was transported to the 8/32 by Bell Labs, with source code adaptations ensuring portability across the 32-bit architecture, overcoming challenges in byte-ordering and register utilization to support the operating system's demands without significant performance degradation. These developments highlighted Interdata's role in pioneering 32-bit minicomputers suitable for advanced operating systems, with the scaling innovations ensuring backward compatibility and forward scalability in instruction execution and memory handling.

Parallel Processing Capabilities

In the late 1970s, Interdata, under Perkin-Elmer's ownership, developed parallel processing features as extensions to its 32-bit minicomputer line, notably the 8/32 series, enabling multi-processor configurations for enhanced computational performance in demanding applications. These extensions were introduced through the Multiport Memory System (MMS) in 1977, which supported up to fourteen 32-bit CPUs sharing common memory while accessing local memory, allowing configurations from simple dual-processor setups to complex systems with multiple memory banks. Building on the foundational 32-bit architecture of the 8/32, this system facilitated aggregate throughputs exceeding 20 megabytes per second in fully expanded setups. Technical details of these multi-processor configurations centered on a multi-bank, multi-port, multi-bus shared memory architecture, where each processor could access up to one million bytes of combined shared and local memory organized into 32 KB or 64 KB modules across up to eight banks. Inter-processor communication relied on shared memory protocols rather than serial or parallel interfaces, using named global common areas in the multiport memory for data exchange, with up to fifteen such areas declarable under the operating system; access control was managed via the "Test and Set" instruction as a semaphore at the assembly level. Hardware features like the Multiport Memory Controller resolved contention among up to seven multiplexors per bank, supporting asynchronous operations and options for bank interleaving (2-way, 4-way, or 8-way) to optimize parallel access, while transfer rates reached 3.2 MB/sec in burst mode. Software support for parallelism was provided by OS/32 MT, a real-time, event-driven multi-tasking operating system that enabled dynamic management of global common areas and supported up to 255 priority levels for concurrent processing, making it suitable for real-time applications in scientific simulations such as flight simulation and seismic analysis. This OS integrated seamlessly with the MMS, allowing transparent data sharing for high-level language programmers and facilitating the division of complex problems across processors without significant communication overhead. Key innovations included load balancing algorithms implemented through service priority schemes in the memory controller, such as sequential or fixed access priorities, which ensured efficient resource allocation among processors and I/O devices in multi-processor environments, reducing contention and enhancing overall system throughput for scientific computing tasks.

Legacy and Impact

Influence on Minicomputer Industry

Interdata played a significant role in advancing the minicomputer industry by introducing one of the first 32-bit systems, the Model 7/32, in 1974, which utilized microcoding to implement a complete instruction set architecture, including floating-point operations, predating mainstream adoption by competitors like Digital Equipment Corporation (DEC), whose VAX series arrived in 1977. This innovation helped popularize 32-bit architectures in the minicomputer market by offering enhanced performance for scientific and engineering applications at a time when most systems were limited to 16 bits. The company's designs emphasized modular construction and expandability, influencing industry standards for scalable minicomputer systems through features like building-block architectures that allowed users to configure hardware for diverse requirements using standard off-the-shelf modules. For instance, the Interdata Model 70 exemplified this approach with its highly modular structure, enabling tailored configurations that promoted flexibility and cost-effectiveness in deployment. These advancements contributed to broader adoption of modular designs across the sector, facilitating easier upgrades and maintenance in competitive environments. Interdata systems found application in demanding computational tasks that foreshadowed supercomputing concepts, such as the Model 8/32's use in high-performance university environments for advanced processing needs. Regarding impact metrics, while specific market share figures for Interdata in the 1970s are not well-documented, the overall minicomputer industry grew rapidly, with worldwide revenues reaching $2.5 billion by 1977, amid competition from over 100 manufacturers including Interdata. The company's contributions are reflected in computing literature through references to its early support for operating systems like UNIX on non-DEC platforms, highlighting its role in software portability and ecosystem development.

Integration with Perkin-Elmer and Broader Applications

Following its acquisition by Perkin-Elmer Corporation in 1973 for $63.6 million, Interdata became the foundation of Perkin-Elmer's Data Systems Group, with operations continuing in Oceanport, New Jersey. This integration allowed Interdata's minicomputer technology to support Perkin-Elmer's core business in analytical instruments, enhancing data processing capabilities for chemical and physical research applications. Perkin-Elmer's systems, derived from Interdata designs such as the 3210 model, were commonly employed in scientific and laboratory environments to handle computational tasks integral to instrument operation and analysis. Interdata's technology found specific applications in astronomy and optics through Perkin-Elmer's projects, including computing support for the development of the Hubble Space Telescope in the 1980s. Perkin-Elmer, as the prime contractor selected by NASA in 1977, utilized its computing division—including systems derived from Interdata—for support in the telescope's optical projects. These computers facilitated simulations and analysis in optical testing, aligning with Perkin-Elmer's broader contributions to space instrumentation, such as laser retroreflectors for Apollo missions and telescope designs like the 33-inch Baker Schmidt installed in 1950. The integration emphasized parallel processing innovations from Interdata, enabling efficient handling of complex datasets in these high-precision scientific endeavors. The Data Systems Group evolved under Perkin-Elmer through the late 1970s and early 1980s, with a shift toward high-end 32-bit minicomputers targeted at specialized markets, though it faced challenges like sales declines in 1982 prompting cost reductions. By 1985, amid Perkin-Elmer's strategic refocus, the computing division was spun off as an independent entity named Concurrent Computer Corporation through a November public offering that raised $37 million, with Perkin-Elmer retaining approximately 80 percent equity initially. This divestiture marked the end of direct Interdata operations under Perkin-Elmer, though the technology continued to influence Concurrent's real-time computing products. Long-term, Interdata's legacy within Perkin-Elmer's computing division contributed to advancements in integrated scientific computing before the 1985 closure of that era, paving the way for Concurrent's expansion into areas like video-on-demand systems and defense applications by the 1990s. The spin-off allowed the technology to persist independently, supporting ongoing innovations in real-time processing that echoed its earlier integrations with Perkin-Elmer's optics and instrumentation work.

References

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  3. https://www.encyclopedia.com/books/politics-and-business-magazines/concurrent-computer-corporation
  4. https://americanhistory.si.edu/collections/nmah_334367
  5. https://www.computinghistory.org.uk/det/28933/Interdata-Model-70-Users-Manual/
  6. https://www.nytimes.com/1974/08/11/archives/a-merger-for-mini-computer-concern-people-and-business.html
  7. https://www.ricomputermuseum.org/collections-gallery/equipment/perkin-elmer-3210
  8. http://bitsavers.trailing-edge.com/pdf/auerbach/Auerbach_Minicomputers_Mar71.pdf
  9. https://www.sec.gov/news/digest/1969/dig040369.pdf
  10. https://ethw.org/Rise_and_Fall_of_Minicomputers
  11. https://www.nytimes.com/1974/03/14/archives/interdata-wooed-by-perkinelmer-accord-in-principle-reached-for.html
  12. http://www.bitsavers.org/magazines/Datamation/19790525.pdf
  13. https://bitsavers.trailing-edge.com/pdf/datapro/datapro_reports_70s-90s/_Survey_Index/70F-400-01_7106_All_About_Minicomputers.pdf
  14. https://www.rcsri.org/collection/interdata-4/
  15. http://www.bitsavers.org/pdf/interdata/16bit/os16/OS16MT2_Brochure_197709.pdf
  16. https://collection.powerhouse.com.au/object/390790
  17. https://bitsavers.computerhistory.org/pdf/interdata/16bit/brochures/Model_2_3_4_Brochure_1968.pdf
  18. http://simh.trailing-edge.com/interdata.html
  19. http://bitsavers.informatik.uni-stuttgart.de/pdf//interdata/32bit/7-32/7-32_Brochure_1973.pdf
  20. http://www.bitsavers.org/pdf/interdata/32bit/7-32/29-405_7-32_UsersMan_Jun76.pdf
  21. http://www.bitsavers.org/pdf/interdata/32bit/7-32/29-399r02_7-32_RefMan_Sep74.pdf
  22. http://bitsavers.informatik.uni-stuttgart.de/pdf/interdata/32bit/8-32/8-32_Brochure_1977.pdf
  23. https://www.tuhs.org/cgi-bin/utree.pl?file=Interdata732
  24. https://www.nokia.com/bell-labs/about/dennis-m-ritchie/portpap.html
  25. http://bitsavers.informatik.uni-stuttgart.de/pdf//interdata/periph/brochures/Multiport_Memory_Brochure_197703.pdf
  26. https://www.referenceforbusiness.com/history2/24/Concurrent-Computer-Corporation.html
  27. https://bitsavers.org/pdf/interdata/32bit/8-32/8-32_HPFP_Brochure_197609.pdf
  28. http://www.bitsavers.org/pdf/datapro/datapro_reports_70s-90s/Perkin-Elmer/M11-683-30_7912_Perkin-Elmer_Series_3200.pdf
  29. http://bitsavers.trailing-edge.com/simh.trailing-edge.com/interdata.html
  30. https://bitsavers.trailing-edge.com/pdf/interdata/16bit/model70/29-266R01_Mod70Maint_Apr72.pdf
  31. https://collections.eng.unimelb.edu.au/imu/?record=enarratives.9
  32. https://historyofcomputercommunications.info/section/2.24/The-Minicomputer-1959-1979/
  33. https://gunkies.org/wiki/Interdata_7/32
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