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Daisy wheel printing

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Metal Daisy Wheel for Xerox & Diablo printers
Plastic Daisy Wheel for Qume printers
Samples of daisy wheel printer output. Actual print is much crisper than these images
The Royal LetterMaster, a budget daisy-wheel printer from the 1980s

Daisy wheel printing is an impact printing technology invented in 1970 by Andrew Gabor[1] at Diablo Data Systems. It uses interchangeable pre-formed type elements, each with typically 96 glyphs, to generate high-quality output comparable to premium typewriters such as the IBM Selectric, but two to three times faster. Daisy wheel printing was used in electronic typewriters, word processors and computers from 1972. The daisy wheel is so named because of its resemblance to the daisy flower.[2]

By 1980 daisy wheel printers had become the dominant technology for high-quality text printing, grossly impacting the dominance of manual and electric typewriters, and forcing dominant companies in that industry, including Brother and Silver Seiko to rapidly adapt — and new companies, e.g., Canon and Xerox, to enter the personal and office market for daisy wheel typewriters. The personal and office printing industry would soon adapt again to the advent of the PC and word processing software.

Dot-matrix impact, thermal, or line printers were used where higher speed or image printing were required and their print quality was acceptable. Both technologies were rapidly superseded for most purposes when dot-based printers, in particular lasers and ink jet printer, capable of printing any characters, graphics, typefaces or fonts, rather than a limited, 96 character set, gradually were able to produce output of comparable quality. Daisy wheel technology is now mostly defunct, though is still found in electronic typewriters.

History

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In 1889 Arthur Irving Jacobs patented a daisy wheel design (U.S. Patent 409,289) that was used on the Victor index typewriter.

A. H. Reiber of Teletype Corporation received U.S. Patent 2,146,380 in 1939 for a daisy wheel printer.

In 1970 a team at Diablo Systems led by engineer Dr Andrew Gabor developed the first commercially successful daisy wheel printer, a device that was faster and more flexible than IBM's Selectric devices, being capable of 30 cps (characters per second), whereas the Selectric operated at 13.4 cps. Dr Andrew Gabor was issued two patents for the invention U.S. Patents 3,954,163 and 3,663,880.

Xerox acquired Diablo that same year. Xerox's Office Product Division had already been buying Diablo printers for its Redactron text editors. After 7 years trying to make Diablo profitable, the OPD focused on developing and selling the Diablo 630 which was mostly bought by companies such as Digital Equipment Corporation.[citation needed] The Diablo 630 could produce letter quality output as good as that produced by an IBM Selectric or Selectric-based printer, but at lower cost and double the speed. A further advantage was that it supported the entire ASCII printing character set. Its servo-controlled carriage also permitted the use of proportional spaced fonts, where characters occupy a different amount of horizontal space according to their width.

The Diablo 630 was so successful that virtually all later daisy wheel printers, as well as many dot matrix printers and even the original Apple Laserwriter either copied its command set or could emulate it. Daisy wheel printers from Diablo and Qume were the dominant high-end output technology for computer and office automation applications by 1980, though high speed non-impact techniques were already entering the market (e.g. IBM 6640 inkjet, Xerox 2700 and IBM 6670 laser). From 1981 onwards the IBM PC's introduction of "Code page 437" with 254 printable glyphs (including 40 shapes specifically for drawing forms), and development of Xerox Star-influenced environments such as the Macintosh, GEM and Windows made bit-mapped approaches more desirable, driving cost reductions for laser printing and higher resolution for impact dot matrix printing.

Xerox later adapted Diablo's daisy wheel technology into a typewriter that sold for less than $50.[citation needed] An automated factory was built near Dallas that took less than 30 minutes to assemble a Xerox typewriter. The Xerox typewriter was well received but never achieved the projected sales numbers due to the advent of the PC and word processing software. The typewriter was later modified to be compatible with PCs but the engineering which made it a low cost device reduced its flexibility.[3] By the mid-1980s daisy wheel technology was rapidly becoming obsolete due to the growing spread of affordable laser and inkjet machines, and daisy wheel machines soon disappeared except for the small remaining typewriter market.

Design

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The print-head and daisy wheel on a Xerox/Diablo D-25 printer.

The heart of the system is an interchangeable metal or plastic "daisy wheel" holding an entire character set as raised characters moulded on each "petal". In use a servo motor rotates the daisy wheel to position the required character between the hammer and the ribbon. The solenoid-operated hammer then fires, driving the character type onto the ribbon and paper to print the character on the paper. The daisy wheel and hammer are mounted on a sliding carriage similar to that used by dot matrix printers.

Different typefaces and sizes can be used by replacing the daisy wheel. It is possible to use multiple fonts within a document: font changing is facilitated by printer device drivers which can position the carriage to the center of the platen and prompt the user to change the wheel before continuing printing. However, printing a document with frequent font changes requiring frequent wheel changes quickly became tedious.

Many daisy wheel machines offer a bold type facility, accomplished by double- or triple-striking the specified character(s); servo-based printers advance the carriage fractionally for a wider (and therefore blacker) character, while cheaper machines perform a carriage return without a line feed to return to the beginning of the line, space through all non-bold text, and restrike each bolded character. The inherent imprecision in attempting to restrike on exactly the same spot after a carriage return provides the same effect as the more expensive servo-based printers, with the unique side effect that as the printer ages and wears, bold text becomes bolder.

Like all other impact printers, daisy wheel printers are noisy.

Bi-directional printing

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Most daisy-wheel printers could print a line and then, using built-in memory, print the following line backwards, from right to left. This saved the time that otherwise would have been needed to return the print head to its starting point. This was sometimes known as 'logic seeking,' and was a feature on some dot-matrix printers as well.

Graphics

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Although the daisy wheel principle is basically inappropriate for printing bitmap graphics, there were attempts to enable them to do so. Most daisy wheel printers supported a relatively coarse and extremely slow graphics mode by printing the image entirely out of dots (formed by the "period" character). This required a mechanism capable of pixel by pixel movement, both horizontally and vertically, and low-end printers were incapable of it.[4] Given the slow speed and the coarse resolution this was not a feasible technique for printing large images. However, it could usefully print a small logo onto a letterhead and then the following letter, all in a single unattended print run without changing the print element.

Daisy wheel printers are capable of producing simplified graphics in the form of ASCII art.

Consideration was also given to optimising graphic printing by changing the glyphs on the daisy wheel to a set that would be able to print all the required bitmap combinations more quickly, without requiring an impact for every single dot. This would have the advantage that vertical dot combinations could be printed in a single impact, without requiring fine rotation control of the platen roller. However it would require a specialised daisy wheel so printing of a letter and letterhead would require a two-step process with a manual wheel change in-between.[5] As the development of this technique post-dated the widespread availability of 24-pin dot matrix printers and coincided with the arrival of affordable laser printers in offices, it was never a popular approach.

Brother Industries manufactured the Twinriter 5 (1985) and 6 (1987) printers which tried to overcome the limitation of the missing graphics capabilities of daisy wheel printers by adding a dot matrix print head to the existing daisy wheel print head, with the former being used for letter quality printing and the latter for drafts and for printing symbols which were not present in the daisy wheel character set.[6][7][8]

Variants

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Thimble printers are closely related to daisy wheel printers. Instead of a flat wheel, the petals are bent to form a cup-shaped "thimble" print element. Introduced by NEC in 1977 as their "Spinwriter" series, the replaceable thimbles each held 128 characters.[9][10]

See also

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References

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  1. ^ Comstock, George E. (2003-08-13). "Oral History of George Comstock" (PDF). Interviewed by Hendrie, Gardner. Mountain View, California, USA: Computer History Museum. CHM X2727.2004. Archived (PDF) from the original on 2017-03-23. Retrieved 2017-03-23.
  2. ^ "Merriam Webster On-line".
  3. ^ Strassman, Paul A. (June 5, 2008). The Computers Nobody Wanted; My Years with Xerox. Strassmann, Inc. pp. 96–97. ISBN 978-1-4276-3270-8.
  4. ^ Hogan, Thom (March 1984). "Creating a letterhead with your daisywheel printer". Creative Computing Magazine. 10 (3): 202.
  5. ^ Kostopoulos, G. K. (February 1989). "Quality graphics for daisy-wheel word processing". IEEE Transactions on Consumer Electronics. 35 (1). IEEE: 16–23. doi:10.1109/30.24649. ISSN 0098-3063.
  6. ^ Linzmayer, Owen W. (November 1985). "Double duty printers". Creative Computing. 11 (11): 72. Archived from the original on 2016-10-31. Retrieved 2016-10-31.
  7. ^ King, Steve (1987-11-23). "Brother Twinriter 6 - Daisy Wheel Drives Us Dotty - A Little Slowly - Dual-Format Printer Saves Spaces, Sacrifies Draft Print Quality". InfoWorld: 57–60. Retrieved 2016-10-31.
  8. ^ Shannon, L. R. (1987-08-25). "Peripherals; Finally, the Right Stuff". The New York Times. Archived from the original on 2016-10-31. Retrieved 2016-10-31.
  9. ^ Cromemco 3355A Printer Operator's Guide (PDF). Cromemco, Inc. March 1980. (Rebadged Model 550 Series Spinwriter)
  10. ^ "NEC Printer Model Information". Retrieved 18 February 2009.