Keypunch

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IBM 026 Keypunch IBM 026 from above.mw.jpg
IBM 026 Keypunch
Keypunch operators at work at the U.S. Social Security Administration in the 1940s SocialSecurity.cardpunching.ssa.jpg
Keypunch operators at work at the U.S. Social Security Administration in the 1940s
Operators compiling hydrographic data for navigation charts on punch cards using the IBM Type 016 Electric Duplicating Key Punch, New Orleans, 1938 NOLAPunchCards1938.jpg
Operators compiling hydrographic data for navigation charts on punch cards using the IBM Type 016 Electric Duplicating Key Punch, New Orleans, 1938

A keypunch is a device for precisely punching holes into stiff paper cards at specific locations as determined by keys struck by a human operator. Other devices included here for that same function include the gang punch, the pantograph punch, and the stamp. The term was also used for similar machines used by humans to transcribe data onto punched tape media.

Contents

For Jacquard looms, the resulting punched cards were joined together to form a paper tape, called a "chain", containing a program that, when read by a loom, directed its operation. [1]

For Hollerith machines and other unit record machines the resulting punched cards contained data to be processed by those machines. For computers equipped with a punched card input/output device the resulting punched cards were either data or programs directing the computer's operation.

Early Hollerith keypunches were manual devices. Later keypunches were electromechanical devices which combined several functions in one unit. These often resembled small desks with keyboards similar to those on typewriters and were equipped with hoppers for blank cards and stackers for punched cards. Some keypunch models could print, at the top of a column, the character represented by the hole(s) punched in that column. The small pieces punched out by a keypunch fell into a chad box, [2] [3] or (at IBM) chip box, or bit bucket .

In many data processing applications, the punched cards were verified by keying exactly the same data a second time, checking to see if the second keying and the punched data were the same (known as two pass verification). There was a great demand for keypunch operators, usually women, [4] who worked full-time on keypunch and verifier machines, often in large keypunch departments with dozens or hundreds of other operators, all performing data input.

In the 1950s, Remington Rand introduced the UNITYPER, which enabled data entry directly to magnetic tape for UNIVAC systems. Mohawk Data Sciences subsequently produced an improved magnetic tape encoder in 1965, which was somewhat successfully marketed as a keypunch replacement. The rise of microprocessors and inexpensive computer terminals led to the development of additional key-to-tape and key-to-disk systems from smaller companies such as Inforex and Pertec. [5]

Keypunches and punched cards were still commonly used for both data and program entry through the 1970s but were rapidly made obsolete by changes in the entry paradigm and by the availability of inexpensive CRT computer terminals. Eliminating the step of transferring punched cards to tape or disk (with the added benefit of saving the cost of the cards themselves) allowed for improved checking and correction during the entry process. The development of video display terminals, interactive timeshared systems and, later, personal computers allowed those who originated the data or program to enter it directly instead of writing it on forms to be entered by keypunch operators.

Stamping Jacquard cards, 1801 through 1890

Jacquard cards were said to be stamped or cut, rather than punched. The first Jacquard cards were stamped by hand, sometimes using a guide plate. An improvement involved placing the card between two perforated metal plates, hinged together, inserting punches according to the desired pattern, and then passing the assembly through a press to cut the card. These essentially manual processes were later replaced by machines. 'Piano machines,' so named for their keys, operated by keyboards and comparable in function to unit record keypunches, became the most common. [1]

Hollerith and IBM keypunches, 1890 through 1930s

Hollerith's Keyboard (pantograph) Punch. This photo is staged; the keyboard layout is for the Farm card (leftmost column is labeled "Kind of Farm") of an Agricultural Census while the paper under the punch shows the layout of the 1890 Population Census card (the actual 1890 census cards had no printing). CTR census machine.JPG
Hollerith's Keyboard (pantograph) Punch. This photo is staged; the keyboard layout is for the Farm card (leftmost column is labeled "Kind of Farm") of an Agricultural Census while the paper under the punch shows the layout of the 1890 Population Census card (the actual 1890 census cards had no printing).
Census worker with Hollerith pantograph punch Card puncher - NARA - 513295.jpg
Census worker with Hollerith pantograph punch

Herman Hollerith's first device for punching cards from the 1890s was ...any ordinary ticket punch, cutting a round hole 3/16 of an inch in diameter. [8] Use of such a punch was facilitated by placing the holes to be used near the edges of the card. Hollerith soon developed a more accurate and simpler to use Keyboard Punch, using a pantograph to link a punch mechanism to a guide pointer that an operator would place over the appropriate mark in a 12 by 20 matrix to line up a manual punch over the correct hole in one of 20 columns. [9]

In 1901 Hollerith patented [10] a mechanism where an operator pressed one of 12 keys to punch a hole, with the card automatically advancing to the next column. This first-generation Type 001 keypunch [11] used 45 columns and round holes. In 1923 The Tabulating Machine Company introduced the first electric keypunch, the Type 011 Electric Keypunch, [12] a similar looking device where each key closed an electrical contact that activated a solenoid which punched the hole. The 80 column punched card format was introduced in 1928. [13] Later Hollerith keypunches included the Type 016 Motor-Driven Electric Duplicating Keypunch [14] [15] (1929), the Type 31 Alphabetical Duplicating Punch [16] (1933), and the Type 32 Alphabetical Printing Punch [17] (1933).

"Alphabetical duplicating keypunches recorded alphabetic information in tabulating cards so that complete words and names, together with numerical data, could be later printed by an alphabetical accounting machine. The Type 31 Alphabetical Duplicating Punch [16] was introduced by IBM in 1933, and it automatically ejected one card and fed another in 0.65 second. These machines were equipped with separate alphabetical and numerical keyboards. The alphabetical keyboard was similar to a conventional manual typewriter [17] except that the shift, tab, backspace and character keys were eliminated, and a skip, release, stacker and '1' key were provided."  IBM Archives [18]

Post-WW II IBM keypunches and verifiers for 80-column cards

A key punch room in the 1960s IBM Keypunch Machines in use.jpg
A key punch room in the 1960s
Hand-operated keypunch
(manufactured by British ICT) (1960s) Hand-operated Card Punch-2.jpg
Hand-operated keypunch

(manufactured by British ICT) (1960s)

Most IBM keypunch and verifiers used a common electrical/mechanical design in their keyboards to encode the mechanical keystrokes. As a key was depressed, a link on the keystem tripped a corresponding set of bails at the top of the keyboard assembly. The bails in turn made (closed) contacts to encode the characters electrically. As each key stroke was detected by the machine, a feed-back circuit energized a pair of magnets with a bail which restored the keystem mechanically, reset the bails performing the electrical encoding, and gave the "feel" and sound to the operator of a completed action. Each machine had a tendency to develop a "feel" of its own based on several variables such as the amount of wear, dirt, and clearance of the bail contacts within the keyboard, as well as factors in the base machine. The keyboards, however, had no provision for adjusting the "feel" other than the correct adjustment of the contacts on the restore bail contacts and the encoding bail contacts. Special function keys such as shift, release, duplication and others, had only electrical contacts under their stems, with no mechanical linkage to the bail assembly for encoding.

IBM keypunches such as the 024, 026, and 029 provided for the mounting of a program card that controlled various functions, such as tabbing and automatic duplication of fields from the previous card. The later 129 used electronic circuit cards to store simple programs written by the keypunch operator.

IBM 024, 026 Card Punches

IBM 026 Printing Card Punch. Note pink program card mounted on the program drum (top center). IBM26.jpg
IBM 026 Printing Card Punch. Note pink program card mounted on the program drum (top center).
An IBM 026 commercial card code IBM 026 card code.png
An IBM 026 commercial card code

The IBM 024 Card Punch and IBM 026 Printing Card Punch [19] were announced in 1949. They were almost identical, with the exception of the printing mechanism. The heart of the 024 and 026 keypunches was a set of twelve precision punches, one per card row, each with an actuator of relatively high power. Punch cards were stepped across the punch one column at a time, and the appropriate punches were activated to create the holes, resulting in a distinctive "chunk, chunk" sound as columns were punched. Both machines could process 51-, 60-, 66-, and 80-column cards. [20]

The 026 could print the punched character above each column. By 1964 there were ten versions with slightly different character sets. The scientific versions printed parentheses, equal sign and plus sign in place of four less frequently used characters in the commercial character sets. [21]

Metal "code plate" character generator from IBM 026 keypunch IBM-026 wireplate.jpg
Metal "code plate" character generator from IBM 026 keypunch
IBM 026 character generator code plate detail showing dot matrix printing pattern IBM26 WirePlate TieClip.jpg
IBM 026 character generator code plate detail showing dot matrix printing pattern
Back of IBM 026 keypunch showing vacuum tubes and other internal components Back of IBM 026 keypunch.agr.jpg
Back of IBM 026 keypunch showing vacuum tubes and other internal components
A group of IBM 026s in use Bundesarchiv B 145 Bild-F031434-0006, Aachen, Technische Hochschule, Rechenzentrum.jpg
A group of IBM 026s in use

Logic consisted of diodes, 25L6 vacuum tubes and relays. The tube circuits used 150VDC, but this voltage was only used to operate the punch-clutch magnet[ clarification needed ]. Most other circuits used 48VDC.

Characters were printed using a 5 × 7 dot matrix array of wires; the device from which it derived the shape of the character was a metal plate, called the "code plate," with space for 1960 pins (35 pins times 56 printable characters). If the dot was not to be printed in a given character, the pin was machined off. By correctly positioning the plate and pressing it against one end of the array of printing wires, only the correct wires were pressed against the ribbon and then the punched card. (This printer mechanism was generally considered by IBM Customer Engineers to be difficult to repair. One of the most common problems was wires breaking in the tightly curved narrow tube between the code plate and the ribbon—extracting the fragments and replacing the bundle of 35 wires was very tedious). The printing mechanism was prone to be damaged if a user attempted to duplicate "binary" cards with non-standard punch patterns. These could cause the code-plate positioning mechanism to try to shift the plate beyond its intended range of motion, sometimes causing damage. Turning off printing did not actually prevent the damage, as many people assumed, because the code-plate mechanism remained engaged with the punch unit and shifted the code plate. Turning off printing only suppressed pressing the printing pins into the ribbon and card.

Raymond Loewy, industrial designer of "streamlined" motifs who also designed railway passenger cars of the 1930s and 1940s, did the award-winning external design of the 026/024 Card Punches for IBM. Their heavy steel construction and rounded corners [22] indeed echo the industrial Art Deco style.

IBM 056 Card Verifier

Two women discussing their work while entering data onto punched cards at Texas A&M in the 1950s. The woman at the right is seated at an IBM 026 keypunch machine. The woman at left is at an IBM 056 Card Verifier. Her job would be to re-enter the data and the verifier machine would check that it matched the data punched onto the cards. Keypunching at Texas A&M2.jpg
Two women discussing their work while entering data onto punched cards at Texas A&M in the 1950s. The woman at the right is seated at an IBM 026 keypunch machine. The woman at left is at an IBM 056 Card Verifier. Her job would be to re-enter the data and the verifier machine would check that it matched the data punched onto the cards.

The IBM 056 was the verifier companion to the 024 Card Punch and 026 Printing Card Punch. The verifier was similar to the 026 keypunch except for a red error lens in the machine cover lower center. The verifier operator entered exactly the same data as the keypunch operator and the verifier machine then checked to see if the punched data matched. Successfully verified cards had a small notch punched on the right hand edge.

The IBM 056 verifier used most of the same mechanical and electrical components as the 024/026 keypunches with the exception of the punch unit and print head. The punch unit had sensing pins in place of the punches. The holes sensed or not sensed would trip a contact bail when the configuration was other than that entered by the verifier operator. This stopped the forward motion of the card, and presented a red error light on the machine cover. The notching mechanism was located in the area occupied by the print mechanism on a 026 printing keypunch. It had a solenoid which drove the notching mechanism, and another that selected the top notch punch or end of card punch.

When an operator keying data to be verified encountered an error, the operator was given a second and third try to re-enter the data that was supposed to be in the field. If the third try was incorrect an error notch was put on the top of the card over the column with the error and the "OK" punch at the end of the card was not enabled. The data on the card could actually be correct, since the verifier operator was just as likely to make an error as the keypunch operator. However, with three tries, the operator was less likely to repeatedly make the same error. Some verifier operators were able to guess the error on the card created by the previous keypunch operator, defeating the purpose of the verify procedure, and thus some machines were altered to allow only one entry and error notched on the second try.[ clarification needed ]

Cards with error notches were re-punched (using an 024 or 026) usually by "duplicating" up to the column in error, then entering the correct data. The duplicating function was accomplished by feeding the card through the punch station without punching it. At the next station sensing pins read the holes present in the original card and transferred the data to the punching station and onto a blank card. Columns with errors were corrected instead of being duplicated. The corrected card was then verified to check the data again and be "OK notched".

Typewriter Card Punches

The first combination of card punch and typewriter, permitting selected text to be typed and punched, was developed by the Powers company in 1925. [23] The IBM 824 Typewriter Card Punch was an IBM 024 where the 024 keyboard was replaced by an IBM electric typewriter. [24] Similarly, the IBM 826 used an IBM 026 Keypunch. [25]

IBM 029 Card Punch

IBM 029 Card Punch IBM card punch 029.JPG
IBM 029 Card Punch
Punched card with EBCDIC character set. Contrast at top enhanced to show the printed characters. Blue-punch-card-front-horiz top-char-contrast-stretched.png
Punched card with EBCDIC character set. Contrast at top enhanced to show the printed characters.

Introduced with System/360 in 1964, the 029 had new character codes for parentheses, equal and plus as well as other new symbols used in the EBCDIC code. The IBM 029 was mechanically similar to the IBM 026 and printed the punched character on the top of the card using the same kind of mechanism as the 026, although it used a larger code plate with 2240 printing-pin sites due to the larger set of characters in EBCDIC.

The 029's logic consisted of wire contact relays on later models and reed relays and diodes on SMS cards for early ones. The more "advanced" reed relays used at first proved to be less reliable than expected, causing IBM to revert to the older-style wire-contact relay-based design. All ran on 48 volts DC, and did not require the vacuum tubes that were used in the 024/026. A common additional feature made available (at additional cost) was the leading zeros feature (termed "Left-Zero"). This was delivered by an additional set of four SMS cards. The field was programmed for leading zeros using the program card. If it was (say) a six digit field, the operator only had to key in the actual value (for example 73). The feature would then fill the field by punching the leading four zeros, followed by the 73, in effect right justifying the field, thus: 000073.

IBM 5924 Key Punch

The IBM 5924 Key Punch was the 029 model T01 attached with a special keyboard in IBM's 1971 announcement of the IBM Kanji System, the keypunch operator's left hand selecting one of 15 shift keys and the right hand selecting one of 240 Kanji characters for that shift. It introduced the computer processing of Chinese, Japanese and Korean languages that typically used large character sets over 10,000 characters.

IBM 059 Card Verifier

The IBM 059 was the Verifier companion to the IBM 029 Card Punch. In design, it differed radically from the earlier 056 verifier, in that it used optical sensing of card holes instead of mechanical sensing pins. This made the 059 much quieter than the 056 (which was often louder than the 024 keypunch). The optical sensors used a single light source, which was distributed to various sites within the machine via fiber-optic lightpipes. Despite the technology, the basic mode of operation remained essentially the same as with the 056.

Ironically, not all verifier operators appreciated the noise reduction. When used in a room also containing 029 keypunch machines, the verifier operators sometimes missed the auditory feedback provided by the loud "thunk" noise emitted by the older 056. Some were known to compensate by hitting the keys harder, sometimes actually wearing out keyboard parts.

IBM 129 Card Data Recorder

An IBM 129 Card Data Recorder IBM 129 Card Data Recorder.jpg
An IBM 129 Card Data Recorder
IBM 129 Combination Keyboard. Card is punched with the letters of the alphabet and the digits 1 through 0. GfhR (14).jpg
IBM 129 Combination Keyboard. Card is punched with the letters of the alphabet and the digits 1 through 0.

Introduced with the System/370 in 1971, the IBM 129 was capable of punching, verifying, and use as an auxiliary, on line, 80 column card reader/punch for some computers. A switch on the keyboard console provided the ability to toggle between the punch and verify modes.

The transistorized IBM 129 Card Data Recorder's primary advantage over other IBM keypunches was that it featured an electronic 80-column buffer to hold the card image. When using earlier IBM keypunches, a keystroke error required the card to be ejected by pressing the Release and Register keys, the error corrected by pressing the Duplicate key until the error column was reached, typing the correct data for the rest of that card, then pressing the Release key and manually removing the bad card from the output card stacker before it was placed in the deck (this required some practice, but quickly became an automatic action that you no longer had to think about). With the 129, a keystroke error could be erased by pressing the Backspace key and re-keyed. The entire 80-column card was punched automatically, as fast as the mechanism could go, when the Release key was pressed.

SLT modules in the IBM 129 IBM 129 SLT modules.jpg
SLT modules in the IBM 129

Logic was in SLT modules on a swing out, wire-wrapped backplane.

A secondary advantage of the 129 was that the speed of the keying operation was not limited by punching each column at the time of the keystroke.

The 129 could store six programs in its memory, selectable by a rotary switch. Unlike earlier keypunch machines, the program cards were read into memory via the regular card-feed path, and were not wrapped around a "program drum".

Thanks to its use of electronic memory, the 129 did not have a separate "read station" with a pin-sense unit to enable duplication of data from one card to the next. Instead, duplication was based on the stored image of the previous card. Cards could also be "read-in" through an optical read unit integrated into the punch station.

Program card

Program card for an IBM 026 at the Computer History Museum. The lever at the top opened the metal clamp holding the card in place. The column-80 edge of the card was inserted under the clamp first. Small fingers on the right side of the clamp helped guide the column-1 edge into position. The lever was then rotated back to secure the card. IBMkeypunchDrumCard.MWichary.jpg
Program card for an IBM 026 at the Computer History Museum. The lever at the top opened the metal clamp holding the card in place. The column-80 edge of the card was inserted under the clamp first. Small fingers on the right side of the clamp helped guide the column-1 edge into position. The lever was then rotated back to secure the card.

IBM 024, 026, and 029 keypunches and their companion verifiers, the 056 and 059, could be programmed to a limited extent using a Program Card, [26] also known as a drum card. The keypunch or verifier could be programmed to automatically advance to the beginning of each field, default to certain character types within the field, duplicate a field from the previous card, and so on. Program cards were an improvement over the Skip Bar used in some earlier keypunches. [27]

The program was encoded on a punched card and could be prepared on any keypunch (a keypunch would operate even if no program card was in place). The program card was wrapped around the program drum, and clamped in place. The drum rotated as the card being punched moved through the punching mechanism. The holes in the program card were sensed by an array of starwheels that would cause levers to rise and fall as the holes in the program card passed beneath the starwheels, activating electrical contacts. The program was encoded in the top six rows [12,11,0,1,2,3]. If the optional Second Program feature was installed, another program could be encoded in the bottom six rows [4,5,6,7,8,9]. A switch let the operator select which program to use. The central cover on the keypunch could be tilted open toward the operator and a locking lever released, allowing the program drum to be removed and replaced.

The program card was punched with characters that controlled its function as follows:

FunctionProgramUsage
#1Char.#2Char.
Field Definition12&44Punch in every column of a field, except the first (left)
Start Automatic Skip11-55Punch in first (left) column of field(s) to skip
Start Automatic Duplication0066Punch in first (left) column of field(s) to duplicate
Alphabetic Shift1177Punch in a column to shift keyboard to Alphabetic mode
Left Zero Print2288Punch in a column to force printing of leading zeros and signs
Print Suppression3399Punch in a column to suppress printing

Many programming languages, such as FORTRAN, RPG, and the IBM Assembler, coded operations in specific card columns, such as 1, 10, 16, 36, and 72. The program card for such a setup might be coded as:

1.......10........20........30........40........50........60........70........80 1AAAAAAAA1AAAAA1AAAAAAAAAAAAAAAAAAA1AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA &&&&&&&&

In this example, if the keypunch operator typed a few characters at the beginning of the card and then pressed the skip key, the keypunch would tab to column 10. When a program code of blank is followed by "Field Definition" (12) (or (4) for program 2), it defines a "Numeric Shift" field. In the example above, columns 72-80 are defined in the program as a Numeric Shift field. In practice, this definition would likely be used for punching a special symbol as a "continuation character" in column 72, and then columns 73-80 could either be punched with a card sequence number or the card could be released at that point, if no further typing was required.

Note: "Field Definition" (12) and "Alphabetic Shift" (1) prints as an A.

If program 2 codes were punched, invalid characters could be generated that the printer did not know how to print, some of which could even damage the printer.

Program cards could automate certain tasks, such as "gang punching", the insertion of a constant field into each card of a deck of cards. For amusement, program cards could even be set up to play music by gang-punching "noisy" characters (characters represented by many holes, usually special characters) and "quiet" numbers and letters in rhythmic patterns.

IBM 5496 Data Recorder for 96 column cards

System/3 with keypunch, right IBM System3 model 10 (1).jpg
System/3 with keypunch, right

In 1969, IBM introduced the System/3 family of low-end business computers which featured a new, smaller-sized, 96 column punched card. [28] The IBM 5496 Data Recorder, a keypunch with print and verify functions, and IBM 5486 Card Sorter were made for these 96-column cards.

Powers, Remington Rand (UNIVAC) keypunches

Beginning around 1906, an employee of the United States Census Bureau, James Powers, developed the Powers Keypunch, which was specific to the census application and had 240 keys. [29] [30] In 1911, Powers formed Powers Accounting Machine Company. That company was taken over by Remington Rand in 1927. [31] Remington Rand's UNIVAC division made keypunches for their 90-column cards and similar machines for the IBM 80-column card. Their 90-column keypunches used a mechanical system developed by Remington Rand to avoid IBM patent issues (long before the acquisition of Eckert–Mauchly Computer Corporation). UNIVAC keypunches stored the sequence of characters for an entire card, then punched all its holes in a single pass, which allowed for corrections instead of wasting a card in case of error.

Remington Rand keypunches included: UNIVAC Card Code Punch Type 306-5, 90 Column Alphabetical (Types 306-2, 306-3), 90 Column Numerical (Types 204-2, 204-3), Portable Electric Punch Type 202, Spot Punch Type 301, and the Automatic Verifying Machine Type 313. [32]

The Type 306-2 provided for verification; the cards were passed through the keypunch a second time and keyed again. The verify-punching of the same cards in the same sequence ... results in the elongation of perforations for correct information. Round perforations indicate incorrect information. Complete and rapid detection of errors is performed mechanically by the Automatic Verifying Machine [33]

The UNIVAC 1710 Verifying Interpreting Punch was introduced in 1969. [34]

Keypunch as a verb

Saying that something would be keypunched (to keypunch as a verb), [35] now that the actual device called a keypunch has become obsolete, [36] refers to data entry. [37]

This use of the verb has replaced the former process, described [38] as "When a key is struck on a keypunch, it prints the character on the top of the card but also punches a series of holes that the computer" [39] can interpret."

Transition to direct data entry

In the 1950s, Remington Rand introduced the UNITYPER, [40] [41] which enabled data entry directly to magnetic tape for UNIVAC systems. Mohawk Data Sciences subsequently produced an improved magnetic tape encoder in 1965, which was somewhat successfully marketed as a keypunch replacement. In the mid-1970s, the rise of microprocessors and inexpensive computer terminals led to the development of additional key-to-tape and key-to-disk systems from smaller companies such as Inforex and Pertec.

Punched cards were still commonly used for data entry and programming until the mid-1980s. However, eliminating the step of transferring punched cards to tape or disk (with the added benefit of saving the cost of the cards themselves) allowed for improved checking and correction during the data entry process. The development of video display terminals, interactive timeshared systems and, later, personal computers allowed workers who originated the data to enter it directly instead of writing it on forms to be entered by data entry clerks.

See also

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The IBM 557 Alphabetic Interpreter allowed holes in punched cards to be interpreted and the punched card characters printed on any row or column, selected by a control panel. Introduced in 1954, the machine was a synchronous system where brushes would glide over a hole in a punched card and contact a brass roller thereby setting up part of a character code.

<span class="mw-page-title-main">Tabulating machine</span> Late 19th-century machine for summarizing information stored on punch cards

The tabulating machine was an electromechanical machine designed to assist in summarizing information stored on punched cards. Invented by Herman Hollerith, the machine was developed to help process data for the 1890 U.S. Census. Later models were widely used for business applications such as accounting and inventory control. It spawned a class of machines, known as unit record equipment, and the data processing industry.

<span class="mw-page-title-main">Computer programming in the punched card era</span> History of computer programming using punch cards

From the invention of computer programming languages up to the mid-1970s, most computer programmers created, edited and stored their programs line by line on punch cards.

<span class="mw-page-title-main">Two-pass verification</span>

Two-pass verification, also called double data entry, is a data entry quality control method that was originally employed when data records were entered onto sequential 80-column Hollerith cards with a keypunch. In the first pass through a set of records, the data keystrokes were entered onto each card as the data entry operator typed them. On the second pass through the batch, an operator at a separate machine, called a verifier, entered the same data. The verifier compared the second operator's keystrokes with the contents of the original card. If there were no differences, a verification notch was punched on the right edge of the card.

Inforex Inc. corporation manufactured and sold key-to-disk data entry systems in the 1970s and mid-1980s. The company was founded by ex-IBM engineers to develop direct data entry systems that allowed information to be entered on terminals and stored directly on disk drives, replacing keypunch machines using punched cards or paper tape, which had been the dominant tools for data entry since the turn of the twentieth century.

Paper data storage refers to the use of paper as a data storage device. This includes writing, illustrating, and the use of data that can be interpreted by a machine or is the result of the functioning of a machine. A defining feature of paper data storage is the ability of humans to produce it with only simple tools and interpret it visually.

<span class="mw-page-title-main">Punched card input/output</span> Computer peripheral device

A computer punched card reader or just computer card reader is a computer input device used to read computer programs in either source or executable form and data from punched cards. A computer card punch is a computer output device that punches holes in cards. Sometimes computer punch card readers were combined with computer card punches and, later, other devices to form multifunction machines.

References

  1. 1 2 Bell, T.F. (1895) Jacquard Weaving and Designing, Longmans, Green And Co.
  2. Business automation, Volume 19, Hitchcock Pub. Co., 1972 p.38
  3. Electronic Design, Volume 22, Issues 19-22, Hayden Pub. Co., 1974, pp.79, 195
  4. IBM Archive: Keypunch operators, 1934, Stockholm
  5. Aspray, W., ed. (1990). Computing before Computers. Iowa State University Press. p. 151. ISBN   0-8138-0047-1.
  6. Truesdell, Leon E. (1965). The Development of Punch Card Tabulation in the Bureau of the Census: 1890-1940. US GPO.
  7. (Truesdell, 1965, p.144)
  8. Truesdell (1965) p.44
  9. This first Hollerith pantograph punch was built for the 1890 census card with 12 rows and 24 columns. Four columns were punched using a gangpunch and the pantograph punch was built for the remaining 20 columns. Truesdell(1965)p.44.
  10. U.S. patent 682,197
  11. Fierheller, George A. (2006). Do Not Fold, Spindle or Mutilate: The 'Hole' Story of Punched Cards (PDF). Stewart Publishing. p. 25. ISBN   1-894183-86-X. An accessible book of recollections (sometimes with errors), with photographs and descriptions of many unit record machines
  12. IBM writes history as if everything had always been IBM. That is not correct, see CTR for correct corporate details. IBM Archive: 1923
  13. Bashe, Charles J.; Johnson, Lyle R; Palmer, John H.; Pugh, Emerson W. (1986). IBM's Early Computers . MIT. pp.  11–12. ISBN   0-262-02225-7.
  14. Type 016 Motor-Driven Electric Duplicating Keypunch
  15. Fierheller (2006) p.25
  16. 1 2 Type 31 Alphabetical Duplicating Punch
  17. 1 2 Type 32 Alphabetical Printing Punch
  18. IBM Archives: Type 031, 032
  19. IBM 026 Keypunch photo (archived)
  20. IBM (1964). Reference Manual—IBM 24, 26 Card Punch. p. 26. A24-0520-2.
  21. IBM (1964). Reference Manual—IBM 24, 26 Card Punch. p. 27. A24-0520-2.
  22. "The IBM 026 Key Punch". www.columbia.edu. Retrieved 12 April 2024.
  23. Know-How Makes Them Great. Remington Rand. 1941.
  24. Fierheller (2006) p.55
  25. Stefan (8 June 2014). "IBM 824-826 Typewriter Card Punch Brochure". Classic Computer Brochures. Retrieved 10 January 2015.
  26. Fierheller (2006) p.27
  27. Fierheller (2006) p.26
  28. IBM Field Engineering Announcement: IBM System/3
  29. Truesdell (1965) pp.119–126
  30. Aspray (ed.) (1990) pp.124–125
  31. A History of Sperry Rand Corporation. 4th printing. Sperry Rand. 1967.
  32. Mecham, Alan D., ed. (1961). Data Processing Equipment Encyclopedia Vol.1 Electromechanical Devices. Gillie Associates.
  33. Mecham (ed.) (1961) pp.197, 357
  34. UNIVAC 1710 keypunch
  35. "to transfer onto punched cards, paper tape, etc, by using a key punch." "Keypunch (verb)".
  36. David Allen (2013). How Mechanics Shaped the Modern World. ISBN   978-3319017013. ... thus resulting in the now extinct term keypunch. This essentially mechanical means of communication remained the primary means of interfacing humans ...
  37. June C. Nash (1989). From Tank Town to High Tech: The Clash of Community and Industrial ... ISBN   088706938X. keypunch it and it would go directly to the computer. It would eliminate the cards
  38. Walter A. Sedelow; Sally Yeates Sedelow (1983). Computers in Language Research. p. 29. ISBN   9027930090.
  39. actually a Card reader
  40. Kurt W. Beyer (2015). Grace Hopper and the Invention of the Information Age. ISBN   978-1483550497. ... 1950, Remington Rand was ... UNITYPER, the ...
  41. "Univac UNITYPER". IThistory.org (IT History Society). 15 December 2015. UNITYPER was an input device for the UNIVAC computer... Remington Rand in the 1950s.

Further reading