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J. Presper Eckert

John Presper Eckert Jr. (April 9, 1919 – June 3, 1995), commonly known as Pres Eckert, was an American electrical engineer and computer pioneer renowned for co-inventing the ENIAC (Electronic Numerical Integrator and Computer), the world's first general-purpose electronic digital computer, which revolutionized computing during World War II.^[1]^[2] Born in Philadelphia, Pennsylvania, Eckert's innovations laid foundational groundwork for modern digital computing, including advancements in vacuum tube technology and stored-program architectures.^[3] Eckert earned a Bachelor of Science in electrical engineering from the University of Pennsylvania's Moore School of Electrical Engineering in 1941, followed by a Master of Science in 1943.^[1] As a part-time laboratory instructor at the Moore School in the early 1940s, he collaborated with physicist John Mauchly, leading to their proposal for an electronic computer to the U.S. Army in 1943.^[1]^[3] Eckert served as chief engineer on the ENIAC project, which was completed in 1945 and publicly unveiled in 1946; he addressed key technical challenges, such as enhancing vacuum tube reliability by operating them at reduced power levels, enabling the machine's unprecedented speed in ballistic calculations.^[3]^[2] Following ENIAC, Eckert co-founded the Electronic Control Company in 1946 (renamed Eckert-Mauchly Computer Corporation in 1949), where he co-designed the BINAC (1949), the first stored-program computer in the United States, and the UNIVAC I (1951), the first commercial digital computer in the United States.^[1]^[2] The company was acquired by Remington Rand in 1950, and Eckert advanced through executive roles, including director of engineering and various vice presidencies at Remington Rand, Sperry Rand, and Unisys, until his retirement in 1989, despite a major patent dispute over ENIAC's invention rights that invalidated their patent in 1973.^[1] His contributions earned him prestigious honors, such as election to the National Academy of Engineering in 1967, the National Medal of Science in 1969, the IEEE Computer Society Pioneer Award in 1980, and an honorary Doctor of Science from the University of Pennsylvania in 1964.^[1]^[2]

Early Life and Education

Birth and Early Influences

John Presper Eckert Jr. was born on April 9, 1919, in Philadelphia, Pennsylvania, to John Presper Eckert Sr., a successful construction businessman known for developing apartment houses and garages, and Ethel M. Hallowell Eckert, a bookkeeper and office manager from a prominent Quaker family with entrepreneurial roots.^[4]^[5] As the only child in a prosperous household that employed servants, Eckert grew up in the Mt. Airy and Germantown neighborhoods of Philadelphia, areas considered affluent suburbs of the city.^[6]^[5] His family's wealth and stability provided a nurturing environment, though his parents initially encouraged a business career aligned with his father's profession rather than his emerging technical inclinations.^[4] From an early age, Eckert displayed a keen interest in technology, influenced by the era's growing fascination with radio in the 1920s. By age five, he was tinkering with electrical devices, and at seven, he built his first radio, experimenting with electronics in a home workshop.^[5] These hands-on activities, including constructing crystal radios and other gadgets, sparked his passion for engineering and laid the foundation for his future innovations, despite limited direct exposure to technology through his father's construction business.^[7]^[5] The family relocated to a larger home on Cliveden Street in Germantown when Eckert was eight, further immersing him in a community supportive of intellectual pursuits. He attended local private schools initially before enrolling at the William Penn Charter School, a Germantown institution emphasizing rigorous academics, including science and mathematics, which honed his analytical skills.^[5]^[7] This formative period culminated in his transition to formal higher education at the University of Pennsylvania in 1937.^[2]

Academic Background

J. Presper Eckert initially enrolled at the University of Pennsylvania's Wharton School in 1937 to study business, at the encouragement of his parents, but soon transferred to the Moore School of Electrical Engineering due to his growing interest in electronics.^[8] This shift aligned with his emerging fascination with electrical systems, building on a childhood hobby of tinkering with radios that had introduced him to basic circuitry.^[8] Eckert completed his Bachelor of Science degree in electrical engineering from the Moore School in 1941.^[1] His coursework emphasized foundational topics in the field, including vacuum tubes, electrical circuits, and introductory concepts in computation and control systems, which were central to the engineering curriculum at the time.^[9] These studies provided him with a solid theoretical grounding in analog and early digital technologies, preparing him for advanced research in computing machinery. During his undergraduate and early graduate years, Eckert gained practical experience through part-time work at the Moore School, where he served as a laboratory assistant and instructor.^[1] Notably, he contributed to the maintenance and improvement of the school's differential analyzers—mechanical analog computers used for solving differential equations—enhancing their speed and precision through hands-on modifications.^[8] This role, which began around 1941, offered invaluable exposure to large-scale computing devices and wartime engineering challenges, including radar timing research.^[8] In 1943, he earned his Master of Science in electrical engineering from the same institution, further solidifying his expertise.^[1]

ENIAC Development

Collaboration with John Mauchly

J. Presper Eckert first met John Mauchly in 1943 at the Moore School of Electrical Engineering at the University of Pennsylvania, where Eckert, a recent graduate serving as an instructor in a defense technology program, encountered Mauchly, a physics professor enrolled as a student.^[9]^[2] Their initial interactions occurred during Mauchly's lectures on computing concepts, sparking discussions that highlighted their complementary strengths: Mauchly's theoretical insights as a physicist and Eckert's practical engineering expertise.^[9]^[10] Both shared a profound frustration with the limitations of existing mechanical computers, such as the differential analyzer, which were too slow for wartime ballistics calculations, leading them to explore electronic alternatives during informal conversations, often over lunch where they sketched ideas on napkins.^[9]^[10] This collaboration crystallized around a vision for a fully electronic digital computer, with Eckert positioned as the lead engineer to translate Mauchly's conceptual framework into feasible hardware designs.^[9]^[2] In April 1943, Eckert and Mauchly, supported by Moore School director John Grist Brainerd, submitted a joint proposal to the U.S. Army Ordnance Department for an electronic general-purpose calculator to compute artillery firing tables.^[10]^[2] The Army approved the project, known initially as Project PX, and signed a contract in June 1943, providing initial funding of $61,700 from the Ordnance Department to initiate development at the Moore School.^[9]^[10]

Design Innovations and Construction

Under J. Presper Eckert's engineering leadership as chief engineer, the ENIAC was designed as a modular system comprising 30 separate panels or units, each dedicated to specific functions such as accumulation, control, and input-output, which facilitated maintenance and upgrades by allowing individual panels to be isolated and repaired without shutting down the entire machine.^[11] This architecture incorporated approximately 18,000 vacuum tubes, 70,000 resistors, and 10,000 capacitors, along with 1,500 relays, resulting in a total weight of 30 tons and a power consumption of around 150 kilowatts, primarily due to the heating of the vacuum tubes.^[12] The machine's reliance on vacuum tube technology for amplification and switching enabled high-speed electronic computation, far surpassing mechanical calculators, though it demanded robust power supplies and cooling systems.^[11] Eckert's key innovations included the adoption of decimal-based arithmetic using decade ring counters, which processed 10-digit decimal numbers rather than binary, aligning with the needs of ballistic calculations and simplifying integration with existing Army tabulating equipment.^[11] He also introduced function tables—portable panels with resistor matrices controlled by switches—for storing and selecting arbitrary mathematical functions, allowing flexibility in programming complex trajectories without full rewiring.^[11] These design choices, developed in close collaboration with John Mauchly's conceptual vision, emphasized practicality for wartime applications over theoretical efficiency.^[13] Construction began in June 1943 at the Moore School of Electrical Engineering, University of Pennsylvania, under a secret U.S. Army contract, with Eckert overseeing a team of engineers, technicians, and over 100 support personnel, including "human computers" who assisted in calculations and wiring.^[14] The project progressed component-by-component, achieving partial operation by mid-1944, and was fully assembled and demonstrated in December 1945, ahead of its public dedication in February 1946.^[11] Over 500 miles of wiring connected the components via plug-and-socket interfaces, enabling reconfiguration but contributing to setup times that could span days for new problems.^[15] Significant challenges arose from the scale and novelty of the build, including heat dissipation from the vacuum tubes, which necessitated a forced-air cooling system that consumed 20 kilowatts and struggled in humid environments, often raising room temperatures dramatically.^[11] Tube reliability was another hurdle, with early failures occurring every few days due to manufacturing inconsistencies, prompting Eckert to implement rigorous life-testing protocols and procure higher-quality tubes from suppliers like RCA to extend mean time between failures.^[11] The wiring complexity, involving thousands of hand-soldered joints and plugs, further complicated assembly and debugging, yet Eckert's modular approach ultimately proved effective in mitigating these issues during the secretive wartime effort.^[15]

Patent Disputes and Initial Impact

In 1947, J. Presper Eckert and John Mauchly filed a patent application for the ENIAC with the U.S. Patent Office on June 26, describing it as an electronic digital computing machine capable of high-speed numerical calculations.^[16] This filing occurred after a contentious dispute with the University of Pennsylvania, where Eckert and Mauchly were employed at the Moore School of Electrical Engineering. The university asserted ownership rights over the invention, citing its policy that intellectual property developed during employment belonged to the institution, particularly since the project was funded by the U.S. Army.^[17] Eckert and Mauchly countered that the ENIAC represented their independent invention, predating formal university involvement, and refused to sign agreements assigning the rights, leading to their resignation from the Moore School in March 1946.^[18] The patent was eventually granted to them in 1964 as U.S. Patent 3,120,606, but it faced further legal challenges; in the 1973 case Honeywell, Inc. v. Sperry Rand Corp., a federal court invalidated it, ruling that key concepts derived from prior work by John Atanasoff and Clifford Berry, rendering the claims non-novel.^[19] Despite these legal battles, ENIAC had a profound initial impact during and immediately after World War II. Commissioned by the U.S. Army's Ballistic Research Laboratory, it was operational from 1945 and dedicated to computing artillery firing tables—complex trajectory calculations essential for accurate shell targeting—which previously took weeks by human "computers" using mechanical calculators but were reduced to hours or days on ENIAC.^[20] Postwar, on February 15, 1946, ENIAC was publicly demonstrated at the University of Pennsylvania, performing live computations such as solving differential equations for ballistic problems in seconds, which captivated scientists and engineers.^[21] This unveiling highlighted its versatility beyond wartime applications, influencing subsequent designs like the EDVAC, which incorporated stored-program concepts to address ENIAC's limitations in reprogramming.^[22] ENIAC earned widespread recognition as the first general-purpose electronic digital computer, capable of being reconfigured for diverse mathematical tasks ranging from simulations to statistical analysis.^[3] However, its programming relied on physical reconfiguration via switches, plugs, and patch cables—requiring up to three weeks for major changes—rather than internal storage of instructions, distinguishing it from later stored-program architectures. This pioneering role established electronic computing as a practical field, paving the way for the postwar explosion in computer development.

Entrepreneurial Ventures

Founding Eckert-Mauchly Computer Corporation

Following frustrations with patent rights over ENIAC claimed by the University of Pennsylvania, J. Presper Eckert resigned from the Moore School of Electrical Engineering on March 31, 1946, alongside John Mauchly.^[23] The pair immediately established the Electronic Control Company in Philadelphia that spring, marking the world's first commercial venture dedicated to electronic digital computers.^[24] On December 22, 1947, the firm was formally incorporated as the Eckert-Mauchly Computer Corporation, with Eckert serving as vice president and chief engineer under Mauchly's presidency.^[25] To support operations, the corporation secured initial funding of $500,000 from investors including the Prudential Insurance Company of America, which helped finance research and development amid limited capital.^[26] The company's early focus centered on prototyping advanced systems, culminating in the BINAC, contracted to Northrop Aircraft in October 1947 and completed in 1949 as the first stored-program electronic computer built and operational in the United States.^[27] This binary machine, using magnetic tape for input/output, served as a demonstrator for commercial viability and informed subsequent designs.^[27] Despite these innovations, the Eckert-Mauchly Computer Corporation grappled with severe financial strains, including cost overruns on the BINAC that exceeded the budget by $178,000, which Eckert and Mauchly personally absorbed.^[28] Survival depended heavily on government and defense-related contracts, such as the Northrop project for guided missile computations, providing essential revenue but tying the firm to military priorities.^[26] Unable to secure independent stability, the corporation was acquired by Remington Rand on February 15, 1950, becoming its Univac Division and paving the way for the later formation of Sperry Rand through a 1955 merger.^[29] Eckert and Mauchly remained with the division to oversee ongoing projects.^[29]

UNIVAC I and Commercialization

Following the founding of the Eckert-Mauchly Computer Corporation, J. Presper Eckert led the engineering team in developing the UNIVAC I, the first commercial digital computer in the United States, which introduced stored-program capabilities and advanced data processing for business applications.^[2]^[1] The machine utilized magnetic tape for input and output via innovative UNISERVO tape drives, enabling efficient handling of large datasets, and featured Eckert's mercury delay-line memory system, which stored up to 1,000 words using acoustic waves in mercury-filled tubes to recirculate data pulses reliably.^[30]^[1] This memory innovation, adapted from Eckert's wartime radar work, significantly reduced complexity compared to earlier designs by minimizing wiring and allowing dynamic data access.^[2] Eckert also simplified programming through plugboard configurations, which allowed operators to set up instructions via physical connections rather than extensive rewiring, making the system more accessible for non-experts in commercial settings.^[1] The UNIVAC I incorporated about 5,000 vacuum tubes, far fewer than the 18,000 in the ENIAC, enhancing reliability and reducing maintenance needs while achieving calculation speeds of approximately 1,000 operations per second for tasks like sorting and arithmetic.^[31] On June 14, 1951, the first UNIVAC I was dedicated and delivered to the U.S. Census Bureau after a contract signed on March 31 of that year, where it processed portions of the 1950 population census and full economic censuses thereafter.^[31]^[30] The commercialization of UNIVAC I marked a pivotal milestone, with Remington Rand acquiring Eckert-Mauchly in 1950 to facilitate production and sales.^[2] In 1951, CBS purchased a unit for election forecasting, and on November 4, 1952, it accurately predicted Dwight D. Eisenhower's landslide victory over Adlai Stevenson based on early returns, demonstrating its real-time analytical power despite initial skepticism from broadcasters.^[32] By 1958, a total of 46 UNIVAC I systems had been sold, establishing the machine's role in transforming data processing for government and business while solidifying Eckert's reputation in commercial computing.^[1]

Later Professional Career

Integration with Remington Rand and Unisys

Following the 1950 acquisition of the Eckert-Mauchly Computer Corporation by Remington Rand, J. Presper Eckert assumed the role of director of engineering for the newly formed Univac Division, where he played a key leadership position in advancing commercial computing initiatives.^[2]^[18] Under his guidance, the division completed development of the UNIVAC II, a vacuum-tube successor to the foundational UNIVAC I that entered production in 1958 and improved reliability for business data processing tasks.^[33] By 1955, Eckert had risen to vice president and director of commercial engineering, overseeing engineering teams focused on scaling production and adapting systems for widespread commercial adoption.^[1] In 1955, Remington Rand merged with the Sperry Corporation to create Sperry Rand, integrating the Univac Division into a larger entity that combined office equipment expertise with computing innovation; Eckert retained his vice presidential role and continued to influence product strategy through the 1960s and 1970s.^[34] During this period, he led efforts to transition to transistor-based systems, culminating in the UNIVAC 1100 series, which debuted in 1962 with the UNIVAC 1107 and offered enhanced performance for scientific and commercial workloads using solid-state technology.^[35] These advancements emphasized modular design and compatibility, enabling applications in data-intensive sectors such as banking for transaction processing and airlines for reservation systems.^[36] A significant project under Eckert's oversight was the 1952 acquisition and integration of Engineering Research Associates (ERA) by Remington Rand, which brought the ERA 1101—a scientific computer—into the fold and was rebranded as the UNIVAC 1101 to align with the division's commercial lineup.^[37] This merger of ERA's engineering talent with Eckert-Mauchly's resources facilitated early explorations into integrated circuits, as seen in later models like the 1965 UNIVAC 1108, and broadened the focus on business-oriented innovations for efficient data handling in industries like finance and transportation.^[38] Eckert's management approach prioritized collaborative engineering teams, fostering an environment that produced diverse computer systems by the 1970s, from high-end mainframes to peripherals tailored for enterprise needs.^[34] Eckert's leadership persisted through corporate evolution, as Sperry Rand merged with Burroughs Corporation in 1986 to form Unisys, where he contributed to the ongoing refinement of the UNIVAC lineage into modern computing platforms before transitioning to consulting.^[1]^[7]

Retirement and Consulting Roles

After more than four decades in the computing industry, J. Presper Eckert retired from Unisys in 1989 at the age of 70.^[1] He had joined the company's predecessor organizations in the late 1940s and remained through subsequent mergers, including the 1986 formation of Unisys from Sperry and Burroughs.^[8] In retirement, Eckert continued to serve as a consultant for Unisys until his death, providing expertise on ongoing technical matters.^[1] He also engaged in efforts to document computing history, including a series of in-depth interviews conducted in 1989 with Alexander Randall, an electrical engineering professor, where he reflected on the ENIAC's development, technical challenges, and misconceptions about early computer inventions.^[39] These discussions highlighted his role in preserving the narrative of pioneering electronic computing. Eckert's health declined in his later years due to leukemia, and he passed away on June 3, 1995, at Bryn Mawr Hospital in Bryn Mawr, Pennsylvania, at the age of 76.^[40] He was survived by his wife, Judith, whom he had married in 1962; daughter Laura E. Phinney; and sons John P. Eckert III, Gregory A. Eckert, and Christopher C. Eckert.^[40]

Technical Contributions and Legacy

Eckert Architecture and Memory Innovations

J. Presper Eckert's architectural contributions in the mid-1940s centered on his proposal for a stored-program computer design outlined in the September 1945 report "Automatic High-Speed Computing: A Progress Report on the EDVAC," co-authored with John Mauchly.^[41] This document advocated for serial processing, where data and instructions were handled sequentially bit by bit, leveraging acoustic delay lines for memory to enable efficient, high-speed computation without the need for parallel binary operations emphasized in later interpretations. Eckert's approach aligned with John von Neumann's June 1945 "First Draft" report, which also described a serial binary machine; Eckert later argued that the foundational stored-program concept should be termed the "Eckert architecture" due to its origins in their collaborative work at the Moore School.^[42] A cornerstone of Eckert's innovations was the mercury delay-line memory, which he invented during World War II radar development and adapted for computing.^[43] This system used sound waves propagating through tubes filled with mercury to store and recirculate data acoustically, offering a reliable alternative to bulky mechanical or electrostatic storage.^[44] Eckert's design, patented in 1953 (filed 1947), achieved capacities of approximately 1,000 11-digit decimal words with access times around 1 millisecond per word in early implementations.^[45] First realized in the BINAC (1949) with 512 31-bit words across dual processors and scaled in the UNIVAC I (1951) to 1,000 words, the mercury delay lines provided up to 120 digits of storage per tube, enabling practical stored-program operation.^[27]^[46] Eckert also championed decimal arithmetic in early computers, favoring it over binary for compatibility with business and scientific applications reliant on human-readable decimal data.^[47] This choice, evident in ENIAC's ring-counter design and carried into UNIVAC, simplified programming for non-binary tasks despite requiring more hardware per digit.^[9] Complementing this, Eckert pioneered modular vacuum tube designs to enhance reliability, incorporating pluggable units and derating techniques—operating tubes below maximum ratings—to mitigate failures in large-scale systems.^[48] These innovations reduced ENIAC's mean time between failures from expected hours to days, proving vacuum tubes viable for computation.^[49] Credit disputes over the stored-program concept persisted into the 1970s, with Eckert asserting in interviews that von Neumann appropriated ideas from Moore School discussions without attribution, publishing them in the "First Draft" to preempt patents and favor public dissemination. In a 1977 oral history, Eckert described von Neumann's actions as self-promotional, emphasizing that the serial stored-program framework stemmed from Eckert-Mauchly proposals predating von Neumann's involvement.^[50] These views underscored Eckert's belief that his engineering focus on practical, serial implementations laid the groundwork for modern computing architectures.

Awards, Recognition, and Enduring Influence

J. Presper Eckert received numerous accolades for his pioneering work in electronic computing. In 1966, he and John Mauchly were jointly awarded the Harry H. Goode Memorial Award by the American Federation of Information Processing Societies, recognizing their contributions to the field of information processing equipment.^[51] In 1968, Eckert was awarded the National Medal of Science, which was presented by President Lyndon B. Johnson in 1969 for his foundational role in creating, developing, and improving high-speed electronic digital computers.^[52] He later received the Harold Pender Award in 1973 from the University of Pennsylvania for distinguished contributions to electrical engineering.^[53] In 1978, Eckert and Mauchly shared the IEEE Emanuel R. Piore Award for their leadership in the design and construction of ENIAC, the first large-scale electronic digital computer.^[54] Additionally, in 1980, Eckert was named a charter recipient of the IEEE Computer Pioneer Award by the IEEE Computer Society, honoring his early innovations in computing technology. Posthumously, in 2002, he was inducted into the National Inventors Hall of Fame for his co-invention of ENIAC, which revolutionized computational capabilities.^[55] Eckert's developments, particularly ENIAC and UNIVAC I, laid critical groundwork for the digital revolution by proving the viability of programmable electronic computers for complex calculations beyond military applications.^[56] These machines shifted computing from mechanical to electronic paradigms, enabling faster processing speeds and broader utility that transformed scientific research and data handling. His efforts in commercializing UNIVAC I marked a pivotal step toward business computing, directly influencing industry leaders like IBM to expedite their own electronic systems, such as the IBM 701, in response to competitive pressures.^[57] This spurred widespread adoption of digital technology in commerce and government, establishing the infrastructure for modern information processing. A brief reference to his delay-line memory innovation underscores how such practical advancements supported these scalable systems. However, Eckert's engineering leadership is often underrepresented in computing histories, which tend to emphasize Mauchly's theoretical vision, despite Eckert's hands-on role in realizing ambitious designs. Gaps persist in historical records, including limited details on Eckert's involvement with the female programmers—such as Kathleen Antonelli, Jean Jennings, and others—who configured ENIAC's wiring and operations under his team's oversight.^[58] Similarly, scant documentation exists on his perspectives regarding computing ethics, such as data privacy or societal impacts during the early adoption phase. Posthumously, his influence endures through exhibits at the Computer History Museum, featuring artifacts from ENIAC and UNIVAC that highlight his foundational contributions to the field.^[59]

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### J. Presper Eckert Biography Summary
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US2629827A - Memory system - Google Patents
This invention relates to a memory system, and various elements thereof, the memory system be ing of a type into which information may be introduced ...
[46]
UNIVAC I Mercury Delay Line Memory
The principal internal storage in the Univac I system is the 1000-word acoustic delay-line memory, consisting of 100 10-word mercury registers. Twelve ...
[47]
5.10 UNIVAC, Part II: Commercialization | Bit by Bit
Nevertheless, Eckert and Mauchly were desperately short of working capital. With only $206,000 in assets, they required at least another $500,000 in funds to ...
[48]
Historical and Economic Development of Computers
“In the early 1940's, J. Presper Eckert was the designer and chief engineer building ENIAC, the first general-purpose all-electronic computer (see story, page ...
[49]
Proof - Penn Engineering
Presper Eckert came up with several design ideas that increased the reliability of the vacuum tubes. Thanks to his robust engineering, and also to conservative ...Missing: modular | Show results with:modular
[50]
[PDF] Oral History Interview with J. Presper Eckert
Oct 28, 1977 · ECKERT: I was a laboratory instructor and he had come down to take courses in electrical engineering, even though he was a physicist. It turned ...Missing: biography | Show results with:biography
[51]
Harry H. Goode Memorial Award - IEEE Computer Society
Harry H. Goode Memorial Award. For achievements in the information processing ... Presper Eckert: For his pioneering contributions to automatic ...
[52]
J. Presper Eckert, Jr. | NSF - National Science Foundation
For pioneering and containuing contributions in creating, developing, and improving the high-speed electronic digital computer. Presented by President Johnson ...<|control11|><|separator|>
[53]
The Harold Pender Award Lecture - Penn Engineering Events |
1973: John Mauchly and J. Presper Eckert – Inventors of ENIAC. 1972: Edward E. David, Jr. – Science Advisor to the President of the United States. About ...<|control11|><|separator|>
[54]
IEEE-LEVEL AWARDS
The award was discontinued in 2013. George R. Stibitz. 1977. J. Presper Eckert. 1978. John W. Mauchly. 1978. Richard W. Hamming. 1979. Lawrence R. Rabiner. 1980.
[55]
J. Presper Eckert - eniac - National Inventors Hall of Fame®
Eckert was born in Philadelphia and attended the University of Pennsylvania. He graduated in 1941 with his B.S. and in 1943 with his M.S., both in electrical ...Missing: early life background
[56]
J. Presper Eckert (1919-1995) - CHM Revolution
An inveterate electronics tinkerer, Philadelphia native J. Presper Eckert had worked for TV pioneer Philo Farnsworth while still in high school.
[57]
IBM Catches Up - CHM Revolution - Computer History Museum
IBM got a jolt in 1951 when it lost the Census Bureau business to UNIVAC. That setback reenergized IBM, which had dominated pre-computer data processing.
[58]
The Women Behind ENIAC - IEEE Spectrum
Nov 21, 2022 · ... J. Presper Eckert and John W. Mauchly were the only ones who had a hand in its development. Invented in 1945, the Electronic Numerical ...
[59]
J. Presper Eckert - 102649743 - CHM - Computer History Museum
This is a black and white side profile shot of J. Presper Eckert against a white background. He is wearing a suit and tie and looking towards the right side ...