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HP LaserJet 5 printerThe Game Boy Pocket Printer, a thermal printer released as a peripheral for the NintendoGame BoyThis is an example of a wide-carriage dot matrix printer, designed for 14-inch (360 mm) wide paper, shown with 8.5-by-14-inch (220 mm × 360 mm) legal paper. Wide carriage printers were often used in the field of businesses, to print accounting records on 11-by-14-inch (280 mm × 360 mm) tractor-feed paper. They were also called "132-column printers".A video showing an inkjet printer while printing a page
A printer is a peripheral machine which makes a durable representation of graphics or text, usually on paper.[1] While most output is human-readable, bar code printers are an example of an expanded use for printers.[2] Different types of printers include 3D printers, inkjet printers, laser printers, and thermal printers.[3]
The first computer printer designed was a mechanically driven apparatus by Charles Babbage for his difference engine in the 19th century; however, his mechanical printer design was not built until 2000.[4] He also had plans for a curve plotter, which would have been the first computer graphics printer if it was built.[5]
The first patented printing mechanism for applying a marking medium to a recording medium or more particularly an electrostatic inking apparatus and a method for electrostatically depositing ink on controlled areas of a receiving medium, was in 1962 by C. R. Winston, Teletype Corporation, using continuous inkjet printing.
The ink was a red stamp-pad ink manufactured by Phillips Process Company of Rochester, NY under the name Clear Print. This patent (US3060429) led to the Teletype Inktronic Printer product delivered to customers in late 1966.[6]
The first compact, lightweight digital printer was the EP-101, invented by Japanese company Epson and released in 1968, according to Epson.[7][8][9]
The first commercial printers generally used mechanisms from electric typewriters and Teletype machines. The demand for higher speed led to the development of new systems specifically for computer use. In the 1980s there were daisy wheel systems similar to typewriters, line printers that produced similar output but at much higher speed, and dot-matrix systems that could mix text and graphics but produced relatively low-quality output. The plotter was used for those requiring high-quality line art like blueprints.
The introduction of the low-cost laser printer in 1984, with the first HP LaserJet,[10] and the addition of PostScript in next year's Apple LaserWriter set off a revolution in printing known as desktop publishing.[11] Laser printers using PostScript mixed text and graphics, like dot-matrix printers, but at quality levels formerly available only from commercial typesetting systems. By 1990, most simple printing tasks like fliers and brochures were now created on personal computers and then laser printed; expensive offset printing systems were being dumped as scrap. The HP Deskjet of 1988 offered the same advantages as a laser printer in terms of flexibility, but produced somewhat lower-quality output (depending on the paper) from much less-expensive mechanisms. Inkjet systems rapidly displaced dot-matrix and daisy-wheel printers from the market. By the 2000s, high-quality printers of this sort had fallen under the $100 price point and became commonplace.
The rapid improvement of internetemail through the 1990s and into the 2000s has largely displaced the need for printing as a means of moving documents, and a wide variety of reliable storage systems means that a "physical backup" is of little benefit today.
Starting around 2010, 3D printing became an area of intense interest, allowing the creation of physical objects with the same sort of effort as an early laser printer required to produce a brochure. As of the 2020s, 3D printing has become a widespread hobby due to the abundance of cheap 3D printer kits, with the most common process being Fused deposition modeling.
Personal printers are mainly designed to support individual users, and may be connected to only a single computer. These printers are designed for low-volume, short-turnaround print jobs, requiring minimal setup time to produce a hard copy of a given document. They are generally slow devices ranging from 6 to around 25 pages per minute (ppm), and the cost per page is relatively high. However, this is offset by the on-demand convenience. Some printers can print documents stored on memory cards or from digital cameras and scanners.
Networked printers
Networked, workgroup or shared printers are designed for high-volume, high-speed printing. They are usually shared by many users on a network and can print at speeds of 45 to around 100 ppm. The Xerox 9700 could achieve 120 ppm.
Card printers
A card printer or ID-card printer is used for printing plastic cards, including ID cards. These can now be customised with important features such as holographic overlays, HoloKotes and watermarks.[citation needed] This is either a direct to card printer (the more feasible option) or a retransfer printer.[citation needed]
Virtual printer
A virtual printer is a piece of computer software whose user interface and API resembles that of a printer driver, but which is not connected with a physical computer printer. A virtual printer can be used to create a file which is an image of the data which would be printed, for archival purposes or as input to another program, for example to create a PDF or to transmit to another system or user.
Barcode printer
A barcode printer is a computer peripheral for printing barcode labels or tags that can be attached to, or printed directly on, physical objects. Barcode printers are commonly used to label cartons before shipment, or to label retail items with UPCs or EANs.
3D printer
A 3D printerA 3D printer is a device for making a three-dimensional object from a 3D model or other electronic data source through additive processes in which successive layers of material (including plastics, metals, food, cement, wood, and other materials) are laid down under computer control. It is called a printer by analogy with an inkjet printer which produces a two-dimensional document by a similar process of depositing a layer of ink on paper.
The choice of print technology has a great effect on the cost of the printer and cost of operation, speed, quality and permanence of documents, and noise. Some printer technologies do not work with certain types of physical media, such as carbon paper or transparencies.
A second aspect of printer technology that is often forgotten is resistance to alteration: liquid ink, such as from an inkjet head or fabric ribbon, becomes absorbed by the paper fibers, so documents printed with liquid ink are more difficult to alter than documents printed with toner or solid inks, which do not penetrate below the paper surface.
Cheques can be printed with liquid ink or on special cheque paper with toner anchorage so that alterations may be detected.[12] The machine-readable lower portion of a cheque must be printed using MICR toner or ink. Banks and other clearing houses employ automation equipment that relies on the magnetic flux from these specially printed characters to function properly.
A laser printer rapidly produces high quality text and graphics. As with digital photocopiers and multifunction printers (MFPs), laser printers employ a xerographic printing process but differ from analog photocopiers in that the image is produced by the direct scanning of a laser beam across the printer's photoreceptor.
Another toner-based printer is the LED printer which uses an array of LEDs instead of a laser to cause toner adhesion to the print drum.
Liquid ink cartridge from Hewlett-Packard HP 845C inkjet printerHP Deskjet, an inkjet printer
Inkjet printers operate by propelling variably sized droplets of liquid ink onto almost any sized page. They are the most common type of computer printer used by consumers.
Solid ink printers, also known as phase-change ink or hot-melt ink printers, are a type of thermal transfer printer, graphics sheet printer or 3D printer . They use solid sticks, crayons, pearls or granular ink materials. Common inks are CMYK-colored ink, similar in consistency to candle wax, which are melted and fed into a piezo crystal operated print-head. A Thermal transfer printhead jets the liquid ink on a rotating, oil coated drum. The paper then passes over the print drum, at which time the image is immediately transferred, or transfixed, to the page. Solid ink printers are most commonly used as color office printers and are excellent at printing on transparencies and other non-porous media. Solid ink is also called phase-change or hot-melt ink and was first used by Data Products and Howtek, Inc., in 1984.[13] Solid ink printers can produce excellent results with text and images. Some solid ink printers have evolved to print 3D models, for example, Visual Impact Corporation[14] of Windham, NH was started by retired Howtek employee, Richard Helinski whose 3D patents US4721635 and then US5136515 was licensed to Sanders Prototype, Inc., later named Solidscape, Inc. Acquisition and operating costs are similar to laser printers. Drawbacks of the technology include high energy consumption and long warm-up times from a cold state. Also, some users complain that the resulting prints are difficult to write on, as the wax tends to repel inks from pens, and are difficult to feed through automatic document feeders, but these traits have been significantly reduced in later models. This type of thermal transfer printer is only available from one manufacturer, Xerox, manufactured as part of their Xerox Phaser office printer line. Previously, solid ink printers were manufactured by Tektronix, but Tektronix sold the printing business to Xerox in 2001.
A dye-sublimation printer (or dye-sub printer) is a printer that employs a printing process that uses heat to transfer dye to a medium such as a plastic card, paper, or canvas. The process is usually to lay one color at a time using a ribbon that has color panels. Dye-sub printers are intended primarily for high-quality color applications, including color photography; and are less well-suited for text. While once the province of high-end print shops, dye-sublimation printers are now increasingly used as dedicated consumer photo printers.
Thermal printers work by selectively heating regions of special heat-sensitive paper. Monochrome thermal printers are used in cash registers, ATMs, gasoline dispensers and some older inexpensive fax machines. Colors can be achieved with special papers and different temperatures and heating rates for different colors; these colored sheets are not required in black-and-white output. One example is Zink (a portmanteau of "zero ink").
Obsolete and special-purpose printing technologies
Impact printers rely on a forcible impact to transfer ink to the media. The impact printer uses a print head that either hits the surface of the ink ribbon, pressing the ink ribbon against the paper (similar to the action of a typewriter), or, less commonly, hits the back of the paper, pressing the paper against the ink ribbon (the IBM 1403 for example). All but the dot matrix printer rely on the use of fully formed characters, letterforms that represent each of the characters that the printer was capable of printing. In addition, most of these printers were limited to monochrome, or sometimes two-color, printing in a single typeface at one time, although bolding and underlining of text could be done by "overstriking", that is, printing two or more impressions either in the same character position or slightly offset. Impact printers varieties include typewriter-derived printers, teletypewriter-derived printers, daisywheel printers, dot matrix printers, and line printers. Dot-matrix printers remain in common use [15] in businesses where multi-part forms are printed. An overview of impact printing[16] contains a detailed description of many of the technologies used.
Typeball print element from IBM Selectric-type printer
Several different computer printers were simply computer-controllable versions of existing electric typewriters. The Friden Flexowriter and IBM Selectric-based printers were the most-common examples. The Flexowriter printed with a conventional typebar mechanism while the Selectric used IBM's well-known "golf ball" printing mechanism. In either case, the letter form then struck a ribbon which was pressed against the paper, printing one character at a time. The maximum speed of the Selectric printer (the faster of the two) was 15.5 characters per second.
The common teleprinter could easily be interfaced with the computer and became very popular except for those computers manufactured by IBM. Some models used a "typebox" that was positioned, in the X- and Y-axes, by a mechanism, and the selected letter form was struck by a hammer. Others used a type cylinder in a similar way as the Selectric typewriters used their type ball. In either case, the letter form then struck a ribbon to print the letterform. Most teleprinters operated at ten characters per second although a few achieved 15 CPS.
Daisy wheel printers operate in much the same fashion as a typewriter. A hammer strikes a wheel with petals, the "daisy wheel", each petal containing a letter form at its tip. The letter form strikes a ribbon of ink, depositing the ink on the page and thus printing a character. By rotating the daisy wheel, different characters are selected for printing. These printers were also referred to as letter-quality printers because they could produce text which was as clear and crisp as a typewriter. The fastest letter-quality printers printed at 30 characters per second.
Sample output from 9-pin dot matrix printer (one character expanded to show detail)
The term dot matrix printer is used for impact printers that use a matrix of small pins to transfer ink to the page.[17] The advantage of dot matrix over other impact printers is that they can produce graphical images in addition to text; however the text is generally of poorer quality than impact printers that use letterforms (type).
Dot-matrix printers can be broadly divided into two major classes:
Dot matrix printers can either be character-based or line-based (that is, a single horizontal series of pixels across the page), referring to the configuration of the print head.
In the 1970s and '80s, dot matrix printers were one of the more common types of printers used for general use, such as for home and small office use. Such printers normally had either 9 or 24 pins on the print head (early 7 pin printers also existed, which did not print descenders). There was a period during the early home computer era when a range of printers were manufactured under many brands such as the Commodore VIC-1525 using the SeikoshaUni-Hammer system. This used a single solenoid with an oblique striker that would be actuated 7 times for each column of 7 vertical pixels while the head was moving at a constant speed. The angle of the striker would align the dots vertically even though the head had moved one dot spacing in the time. The vertical dot position was controlled by a synchronized longitudinally ribbed platen behind the paper that rotated rapidly with a rib moving vertically seven dot spacings in the time it took to print one pixel column.[18] 24-pin print heads were able to print at a higher quality and started to offer additional type styles and were marketed as Near Letter Quality by some vendors. Once the price of inkjet printers dropped to the point where they were competitive with dot matrix printers, dot matrix printers began to fall out of favour for general use.
Some dot matrix printers, such as the NEC P6300, can be upgraded to print in color. This is achieved through the use of a four-color ribbon mounted on a mechanism (provided in an upgrade kit that replaces the standard black ribbon mechanism after installation) that raises and lowers the ribbons as needed. Color graphics are generally printed in four passes at standard resolution, thus slowing down printing considerably. As a result, color graphics can take up to four times longer to print than standard monochrome graphics, or up to 8–16 times as long at high resolution mode.
Dot matrix printers are still commonly used in low-cost, low-quality applications such as cash registers, or in demanding, very high volume applications like invoice printing. Impact printing, unlike laser printing, allows the pressure of the print head to be applied to a stack of two or more forms to print multi-part documents such as sales invoices and credit card receipts using continuous stationery with carbonless copy paper. It also has security advantages as ink impressed into a paper matrix by force is harder to erase invisibly. Dot-matrix printers were being superseded even as receipt printers after the end of the twentieth century.
Line printers print an entire line of text at a time. Four principal designs exist.
Print drum from drum printer
Drum printers, where a horizontally mounted rotating drum carries the entire character set of the printer repeated in each printable character position. The IBM 1132 printer is an example of a drum printer.[19] Drum printers are also found in adding machines and other numeric printers (POS), the dimensions are compact as only a dozen characters need to be supported.[20]
IBM 1403 line printer
Chain or train printers, where the character set is arranged multiple times around a linked chain or a set of character slugs in a track traveling horizontally past the print line. The IBM 1403 is perhaps the most popular and comes in both chain and train varieties. The band printer is a later variant where the characters are embossed on a flexible steel band. The LP27 from Digital Equipment Corporation is a band printer.
Bar printers, where the character set is attached to a solid bar that moves horizontally along the print line, such as the IBM 1443.[21]
A fourth design, used mainly on very early printers such as the IBM 402, features independent type bars, one for each printable position. Each bar contains the character set to be printed. The bars move vertically to position the character to be printed in front of the print hammer.[22]
In each case, to print a line, precisely timed hammers strike against the back of the paper at the exact moment that the correct character to be printed is passing in front of the paper. The paper presses forward against a ribbon which then presses against the character form and the impression of the character form is printed onto the paper. Each system could have slight timing issues, which could cause minor misalignment of the resulting printed characters. For drum or typebar printers, this appeared as vertical misalignment, with characters being printed slightly above or below the rest of the line. In chain or bar printers, the misalignment was horizontal, with printed characters being crowded closer together or farther apart. This was much less noticeable to human vision than vertical misalignment, where characters seemed to bounce up and down in the line, so they were considered as higher quality print.
Comb printers, also called line matrix printers, represent the fifth major design. These printers are a hybrid of dot matrix printing and line printing. In these printers, a comb of hammers prints a portion of a row of pixels at one time, such as every eighth pixel. By shifting the comb back and forth slightly, the entire pixel row can be printed, continuing the example, in just eight cycles. The paper then advances, and the next pixel row is printed. Because far less motion is involved than in a conventional dot matrix printer, these printers are very fast compared to dot matrix printers and are competitive in speed with formed-character line printers while also being able to print dot matrix graphics. The Printronix P7000 series of line matrix printers are still manufactured as of 2013.
Line printers are the fastest of all impact printers and are used for bulk printing in large computer centres. A line printer can print at 1100 lines per minute or faster, frequently printing pages more rapidly than many current laser printers. On the other hand, the mechanical components of line printers operate with tight tolerances and require regular preventive maintenance (PM) to produce a top quality print. They are virtually never used with personal computers and have now been replaced by high-speed laser printers. The legacy of line printers lives on in many operating systems, which use the abbreviations "lp", "lpr", or "LPT" to refer to printers.
Liquid ink electrostatic printers use a chemical coated paper, which is charged by the print head according to the image of the document.[23] The paper is passed near a pool of liquid ink with the opposite charge. The charged areas of the paper attract the ink and thus form the image. This process was developed from the process of electrostatic copying.[24] Color reproduction is very accurate, and because there is no heating the scale distortion is less than ±0.1%. (All laser printers have an accuracy of ±1%.)
Worldwide, most survey offices used this printer before color inkjet plotters become popular. Liquid ink electrostatic printers were mostly available in 36 to 54 inches (910 to 1,370 mm) width and also 6 color printing. These were also used to print large billboards. It was first introduced by Versatec, which was later bought by Xerox. 3M also used to make these printers.[25]
Pen-based plotters were an alternate printing technology once common in engineering and architectural firms. Pen-based plotters rely on contact with the paper (but not impact, per se) and special purpose pens that are mechanically run over the paper to create text and images. Since the pens output continuous lines, they were able to produce technical drawings of higher resolution than was achievable with dot-matrix technology.[26] Some plotters used roll-fed paper, and therefore had a minimal restriction on the size of the output in one dimension. These plotters were capable of producing quite sizable drawings.
Printers can be connected to computers in many ways: directly by a dedicated data cable such as the USB, through a short-range radio like Bluetooth, a local area network using cables (such as the Ethernet) or radio (such as WiFi), or on a standalone basis without a computer, using a memory card or other portable data storage device.
Most printers other than line printers accept control characters or unique character sequences to control various printer functions. These may range from shifting from lower to upper case or from black to red ribbon on typewriter printers to switching fonts and changing character sizes and colors on raster printers. Early printer controls were not standardized, with each manufacturer's equipment having its own set. The IBM Personal Printer Data Stream (PPDS) became a commonly used command set for dot-matrix printers.
The speed of early printers was measured in units of characters per minute (cpm) for character printers, or lines per minute (lpm) for line printers. Modern printers are measured in pages per minute (ppm). These measures are used primarily as a marketing tool, and are not as well standardised as toner yields. Usually pages per minute refers to sparse monochrome office documents, rather than dense pictures which usually print much more slowly, especially color images. Speeds in ppm usually apply to A4 paper in most countries in the world, and letter paper size, about 6% shorter, in North America.
Some printers can process all four types of data, others not.
Character printers, such as daisy wheel printers, can handle only plain text data or rather simple point plots.
Pen plotters typically process vector images. Inkjet based plotters can adequately reproduce all four.
Modern printing technology, such as laser printers and inkjet printers, can adequately reproduce all four. This is especially true of printers equipped with support for PCL or PostScript, which includes the vast majority of printers produced today.
Today it is possible to print everything (even plain text) by sending ready bitmapped images to the printer. This allows better control over formatting, especially among machines from different vendors. Many printer drivers do not use the text mode at all, even if the printer is capable of it.[7]
A monochrome printer can only produce monochrome images, with only shades of a single color. Most printers can produce only two colors, black (ink) and white (no ink). With half-tonning techniques, however, such a printer can produce acceptable grey-scale images too
A color printer can produce images of multiple colors. A photo printer is a color printer that can produce images that mimic the color range (gamut) and resolution of prints made from photographic film.
The page yield is the number of pages that can be printed from a toner cartridge or ink cartridge—before the cartridge needs to be refilled or replaced.
The actual number of pages yielded by a specific cartridge depends on a number of factors.[27]
For a fair comparison, many laser printer manufacturers use the ISO/IEC 19752 process to measure the toner cartridge yield.[28][29]
In order to fairly compare operating expenses of printers with a relatively small ink cartridge to printers with a larger, more expensive toner cartridge that typically holds more toner and so prints more pages before the cartridge needs to be replaced, many people prefer to estimate operating expenses in terms of cost per page (CPP).[28]
Retailers often apply the "razor and blades" model: a company may sell a printer at cost and make profits on the ink cartridge, paper, or some other replacement part. This has caused legal disputes regarding the right of companies other than the printer manufacturer to sell compatible ink cartridges. To protect their business model, several manufacturers invest heavily in developing new cartridge technology and patenting it.
Other manufacturers, in reaction to the challenges from using this business model, choose to make more money on printers and less on ink, promoting the latter through their advertising campaigns. Finally, this generates two clearly different proposals: "cheap printer – expensive ink" or "expensive printer – cheap ink". Ultimately, the consumer decision depends on their reference interest rate or their time preference. From an economics viewpoint, there is a clear trade-off between cost per copy and cost of the printer.
Printer steganography is a type of steganography – "hiding data within data"[30] – produced by color printers, including Brother, Canon, Dell, Epson, HP, IBM, Konica Minolta, Kyocera, Lanier, Lexmark, Ricoh, Toshiba and Xerox[31] brand color laser printers, where tiny yellow dots are added to each page. The dots are barely visible and contain encoded printer serial numbers, as well as date and time stamps.[32]
^Jim, Haynes. "Archivist". Southwest Museum of Engineering Communications and Computation. Archived from the original on 21 October 2021. Retrieved 29 May 2021.
^ ab
[ "Printer & Page Yield Overview"].
Hewlett-Packard.
^"ISO Page Yields"Archived 6 August 2017 at the Wayback Machine.
quote: "Many original equipment manufacturers of printers and multifunction products (MFPs), including Lexmark, utilize the international industry standards for page yields (ISO/IEC 19752, 19798, and 24711)."
^Artz, D. (2001). "Digital steganography: Hiding data within data". IEEE Internet Computing. 5 (3): 75–80. doi:10.1109/4236.935180.
A printer is a peripheral device connected to a computer that produces physical copies, known as hard copies, of digital documents containing text, images, or graphics, typically on paper or other media.[1]As one of the essential output devices in computing, printers convert electronic data into tangible form using various technologies, enabling users to review, share, or archive information offline.The evolution of printers began with mechanical prototypes in the 19th century, such as Charles Babbage's designs for his Difference Engine, but the first practical computer printer emerged in the 1950s with line printers like the IBM 1403, which could output up to 1,100 lines per minute using impact mechanisms.[2][3]Key types include impact printers, which physically strike an inked ribbon against the paper (e.g., dot-matrix models), and non-impact printers, which use thermal, inkjet, or laser technologies to form images without contact, with laser printers dominating modern office use for their speed and precision since their commercialization by Xerox in 1977.[4]Contemporary printers often incorporate multifunction capabilities, such as scanning, copying, and faxing, and connect via networks or wireless protocols like Wi-Fi, supporting high-resolution outputs with resolutions up to 2400 dpi or more and sustainable features like recycled materials.[1][5]
History
Early mechanical printers
The origins of mechanical printers in computing trace back to Charles Babbage's 1822 design for his Difference Engine, a mechanical calculator intended to automate the production of mathematical tables previously computed by hand. Babbage integrated punch-card control, borrowed from Jacquard's automated loom, to program the machine's operations, while the output mechanism employed rotating printing wheels to ink numerical results directly onto paper and simultaneously create stereotypes—impressions in soft material like plaster for casting metal printing plates. This design aimed to eliminate errors in manual tabulation and represented an early effort to mechanize data output for scientific and navigational purposes.[6]A pivotal innovation occurred in 1938 when American physicist Chester Carlson invented xerography, the first electrostatic dry-printing process suitable for computational applications. Carlson's six-step method began by uniformly charging a photoconductive surface, such as selenium-coated paper, to a positive voltage; exposure to an image via light discharged areas corresponding to the dark parts of the original, forming a latent electrostatic image. Fine powdered ink, known as toner and oppositely charged, was then applied and adhered selectively to the discharged regions before the entire image was transferred to a receiving surface and fused in place, enabling clean, dry reproductions without wet chemicals. This breakthrough shifted printing from mechanical impact to electrostatic attraction, influencing later computer output devices.[7]By 1953, Remington Rand developed the first high-speed printer for the UNIVAC I computer, a drum-based line printer that advanced automated output in electronic computing. The mechanism used a rotating drum with raised characters that struck an inked ribbon against paper, achieving speeds of up to 600 lines per minute at 120 characters per line, far surpassing earlier manual or low-speed alternatives. This printer facilitated rapid generation of computational results, bridging mechanical printing principles with emerging digital systems.[8]These early mechanical printers embodied the transition from manual typesetting—reliant on human labor for arranging type and pressing sheets—to automated, machine-driven output in computing, enabling precise, scalable reproduction of numerical and textual data for scientific and administrative use.[9]
Electromechanical and digital developments
The transition from purely mechanical printing to electromechanical systems in the mid-20th century marked a significant advancement, integrating electronic controls with impact mechanisms to enable faster, more reliable output for early computers, building briefly on xerographic principles for toner transfer explored in prior mechanical eras. One pioneering example was the 1957 UNIVAC high-speed line printer, which utilized magnetic tape input to drive solenoid-operated hammers striking against a rotating type cylinder, achieving speeds of up to 600 lines per minute across 120 print positions. This design allowed for efficient batch processing of data from magnetic tapes, representing an early fusion of electronic signaling and mechanical impact for digital output.In the late 1960s and early 1970s, character-based printers emerged, offering improved versatility for alphanumeric printing. The Centronics Model 101, introduced in 1970, was among the first commercial dot matrix impact printers, featuring a serial print head with seven solenoid-driven wires forming a 5x7 dot matrix for characters, and a tractor-feed mechanism that gripped continuous forms via perforated edges to ensure precise paper advancement.[10][11] This configuration enabled speeds of up to 165 characters per second while accommodating fanfold paper, making it suitable for early minicomputer and terminal applications.Daisy-wheel and similar rotary impact printers further refined print quality in the 1970s by employing interchangeable type elements. IBM's Golf Ball mechanism, adapted from the 1961 Selectric typewriter for printing terminals like the IBM 2741 in the early 1970s, used a spherical, rotating typeface element that tilted and spun to position characters, striking an inked ribbon against the paper at speeds of approximately 15 characters per second.[12] This electromechanical approach provided near-letter-quality output with support for upper- and lower-case fonts, bridging the gap between typewriter precision and computer-driven printing.Early explorations into non-impact technologies also began in the 1970s, paving the way for digital versatility. The IBM 4640, unveiled as a prototype in 1976, employed continuous inkjet technology where a steady stream of ink droplets was generated using piezoelectric vibration for precise drop formation, followed by electrostatic deflection to direct streams onto the paper, enabling non-contact printing for word processing peripherals.[13]The culmination of these developments arrived in 1984 with the Hewlett-Packard LaserJet, the first affordable desktop laser printer priced at around $3,500, which integrated a Canon CX engine to achieve 300 dpi resolution at 8 pages per minute using electrophotographic processes controlled by digital signals.[14][15] This model democratized high-quality, high-speed printing for personal computers, setting the standard for office environments.
Modern innovations and trends
In the 1990s, the printing industry saw the emergence of multifunction printers (MFPs) that integrated printing, scanning, and faxing capabilities into single devices, enhancing home and office productivity by reducing the need for multiple machines. A seminal example was Hewlett-Packard's OfficeJet series, introduced in 1994 as the first all-in-one desktop device combining these functions in a compact form factor.[16] These MFPs gained further traction with the adoption of USB connectivity in the mid-to-late 1990s, such as in HP's DeskJet models starting around 1998, which simplified plug-and-play integration with personal computers and accelerated the shift from parallel ports.[17]The 2000s marked a transition to wireless and networked printing, enabling seamless sharing across devices and locations without physical cables, which broadened accessibility in multi-user environments. This era's innovations included the development of standards for Wi-Fi-enabled printers, allowing integration into home and office networks. A key milestone was Apple's introduction of the AirPrint protocol in 2010, which facilitated driverless wireless printing from iOS and macOS devices to compatible printers, revolutionizing mobile integration.[18]During the 2010s, advancements in LED printing technology improved energy efficiency and print quality by using light-emitting diodes to expose the imaging drum more precisely than traditional lasers, resulting in compact, high-speed devices suitable for enterprise use. Complementing this, Epson launched its EcoTank series in 2010, featuring high-capacity, refillable ink tanks that replaced disposable cartridges, significantly lowering long-term costs—up to 90% savings on ink expenses for users printing thousands of pages annually.[19]In the 2020s, sustainability has driven innovations like biodegradable inks and toners, with HP certifying its DesignJet 712 water-based inks in 2024 for environmental compliance, including reduced volatile organic compounds and recyclability.[20] Similarly, Canon has advanced eco-conscious toner formulations to minimize environmental impact while maintaining performance in high-volume printing.[21] Enterprise printers increasingly incorporate AI-driven predictive maintenance, using machine learning to analyze sensor data and forecast failures, reducing downtime by up to 40% in commercial fleets. Cloud printing services have evolved beyond Google Cloud Print, discontinued in 2020, with successors like PaperCut Mobility Print emerging by 2023 to support secure, remote job submission across hybrid networks.[22][23]Looking to 2025, market projections emphasize printers optimized for hybrid work environments, featuring enhanced security protocols like zero-trust authentication and remote access controls to mitigate cyber risks in distributed setups. The integration of 5G connectivity is anticipated to enable faster, more reliable remote printing from mobile devices, supporting a projected 55% adoption rate of cloud-based solutions amid ongoing remote workforce trends.[24][25]
Printing Technologies
Toner-based printing
Toner-based printing, commonly referred to as electrophotography or xerography, employs dry toner powder in an electrostatic process to produce high-quality text and graphics on paper, primarily in laser and LED printers.[26] The technology relies on a photoconductive surface to form a latent image that attracts charged toner particles, which are then transferred and permanently affixed to the printing medium.The electrophotographic process begins with uniformly charging the surface of a photoconductor drum, typically to a negative potential of around -600 volts, using a charge roller or corona wire.[27] A laser beam in laser printers, or an array of light-emitting diodes in LED printers, then selectively exposes the charged drum to light, discharging specific areas to create an invisible latent electrostatic image corresponding to the desired print content.[26] Negatively charged toner particles, consisting of polymer resins, pigments, and additives with particle sizes typically ranging from 5 to 10 microns, are brought into contact with the drum by the developer unit, where they adhere electrostatically to the discharged regions.[28] The developed toner image on the drum is subsequently transferred to the paper, which has been given a positive charge by the transfer roller, attracting the toner away from the drum. Finally, the toner is fused to the paper in the fuser assembly, where heat (at temperatures of 180-220°C) and pressure melt the polymer particles, bonding them permanently to the surface while a quenching step discharges any residual charge on the drum for the next cycle.[29]Key components of toner-based systems include the toner itself, which is a fine powder of thermoplastic polymer particles; the developer unit, which mixes toner with carrier beads to apply it evenly to the latent image; the fuser assembly, comprising heated rollers for permanent adhesion; and a waste toner collection mechanism to remove residual particles from the drum after transfer.[30] In laser printers, the imaging system uses a modulated laser beam scanned across the drum by a rotating polygonal mirror, enabling precise line-by-line exposure.[31] By contrast, LED printers employ a fixed linear array of thousands of LEDs to illuminate the entire width of the drum simultaneously, eliminating the need for moving mirrors and reducing mechanical complexity.[31]Toner-based printers offer advantages such as high print speeds of 20-50 pages per minute and robust durability for high-volume applications, making them ideal for office environments.[32] However, they typically involve higher initial purchase costs than alternative technologies, with toner cartridge yields ranging from 1,500 to 10,000 pages depending on capacity.[33] Page yield is standardized under ISO/IEC 19752, which tests cartridges by printing documents with 5% toner coverage per page until depletion.[34] The first commercial laser printer utilizing this process was introduced by Xerox in 1977.[35]
Ink-based printing
Ink-based printing encompasses technologies that deliver liquid ink directly onto printing media, with inkjet systems being the predominant method for versatile color and photographic output. These systems operate on the drop-on-demand principle, where ink droplets are precisely ejected from microscopic nozzles only when required, enabling high-resolution imaging on various substrates like paper, film, and textiles. Inkjet printers excel in producing vibrant, full-color prints at a lower initial cost compared to alternatives, making them ideal for home, office, and professional photo applications.[36]The core of inkjet technology lies in two primary ejection mechanisms: thermal and piezoelectric. In thermal inkjet, also known as bubble jet and pioneered by Canon, a thin-film resistor rapidly heats the ink in a chamber, creating a vapor bubble that expands and forces out a droplet through the nozzle before collapsing to draw in fresh ink. This process ejects droplets typically ranging from 1 to 50 picoliters at firing frequencies of 10 to 20 kHz, allowing for rapid, compact printheads suitable for consumer devices. In contrast, piezoelectric inkjet, as used by Epson, applies voltage to a piezoelectric crystal that deforms the ink chamber walls, generating pressure to propel droplets without heat, which accommodates a broader range of ink viscosities and enables smaller drop sizes down to 1.5 picoliters while maintaining similar frequencies. These methods originated from electromechanical prototypes in the mid-20th century, evolving into reliable digital systems by the 1980s.[36][37][38]Ink formulations vary to suit different applications, with dye-based and pigment-based types dominating consumer inkjets. Dye-based inks dissolve colorants in a liquid carrier, typically water, yielding vibrant, high-saturation colors ideal for glossy photo printing but prone to fading under light exposure. Pigment-based inks suspend fine solid particles in the carrier, providing superior fade resistance and waterfastness for archival documents, though they may appear slightly less vivid on certain media. For industrial uses, UV-curable inks incorporate photoinitiators that solidify upon ultraviolet light exposure, enabling durable prints on non-porous surfaces like plastics without solvents.[39][40][41]Nozzle array designs are critical for achieving precision and speed, featuring linear or staggered arrays of thousands of nozzles integrated into silicon or polymer chips. Modern printheads can incorporate up to 1,800 to 2,400 nozzles per inch, enabling drop-on-demand placement with resolutions up to 4,800 x 1,200 dots per inch for sharp, detailed output. This high density allows variable droplet volumes and multi-pass printing to build layers for enhanced color depth and gradient smoothness.[42][43]Maintenance routines are essential to mitigate issues like nozzle clogging from dried ink residues. Automated head cleaning cycles periodically flush ink through the nozzles using suction or wiping mechanisms, often initiated manually or on a schedule to restore flow. Ink delivery systems differ between replaceable cartridges, which integrate the printhead and supply limited volumes, and refillable tank systems, which separate the head from large reservoirs for cost-effective, high-volume printing. In the 2020s, supertank models like Epson's EcoTank series provide yields up to 7,500 black pages per refill, reducing waste and per-page costs for frequent users.[44][45]Environmentally, water-based inks in inkjets offer advantages through their biocompatibility and recyclability, as the aqueous carrier evaporates cleanly, leaving minimal residues on paper for easier processing in recycling streams. However, the drying process can release volatile organic compounds (VOCs) from additives, contributing to indoor air emissions, though modern formulations significantly reduce these compared to solvent-based alternatives.[46][47]
Thermal and impact printing
Thermal printing encompasses two primary variants: direct thermal and thermal transfer, both relying on heat to produce images without the use of liquid inks.[48] In direct thermal printing, heat from resistive heating elements, typically operating at temperatures between 70°C and 100°C, causes a heat-sensitive coating on special paper to darken and form the image.[49]Thermal transfer printing, by contrast, applies heat to a wax- or resin-based ribbon, melting the material onto the printing medium for more durable output.[48] These methods achieve resolutions commonly up to 300 dpi, suitable for clear text and simple graphics, though higher resolutions like 600 dpi are available in specialized models.[50]Impact printing, a contact-based mechanical process, uses physical force to transfer ink from a ribbon to the medium, often producing noise and suited for multi-part forms.[51] Dot matrix printers employ electromagnetic pins—typically arranged in 9- to 24-pin configurations—that strike the ribbon to form characters or dots, with representative speeds around 240 to 550 characters per second (cps) in draft mode. Line printers, prevalent in the 1970s for high-volume data processing, utilized rotating drums or chains with embossed characters to print entire lines simultaneously, achieving speeds exceeding 1,000 lines per minute (lpm).[8] These systems evolved from early electromechanical designs, providing reliable output for business applications despite their mechanical complexity.[52]Thermal and impact printers find niche applications in point-of-sale (POS) systems, label production, and accessibility tools, where durability and low maintenance outweigh limitations in color or speed. For instance, Epson's TM series thermal printers are widely used for generating POS receipts due to their compact design and fast, silent operation on heat-sensitive paper rolls.[53] Braille embossers, often based on impact mechanisms, raise dots on thick paper to create tactile documents, enabling access for visually impaired users through specialized translation software.[54] However, both technologies are largely monochrome, with thermal prints prone to fading from light or heat exposure and impact methods causing media wear from repeated strikes.[55] Impact printers generate significant noise, typically 60-80 dB, making them unsuitable for quiet environments.[56]Energy consumption in thermal printing is notably low, often around 0.5-2 W per line, contributing to their efficiency in intermittent use scenarios like receipt printing.[57] Despite these advantages, thermal and impact methods have seen declining adoption in general computing, driven by the affordability and versatility of inkjet printers, which offer color capabilities at lower per-unit costs for home and office use.[57]
Specialized and emerging technologies
Three-dimensional (3D) printers represent a specialized evolution in computing-driven output devices, enabling the additive fabrication of physical objects from digital models. Fused deposition modeling (FDM), a prevalent 3D printing technique, extrudes thermoplastic filaments—such as acrylonitrile butadiene styrene (ABS) or polylactic acid (PLA)—through a heated nozzle, depositing material layer by layer to build complex geometries with resolutions typically ranging from 0.1 to 0.3 mm in layer thickness.[58][59] This process is intrinsically linked to computing through computer-aided design (CAD) software, which generates stereolithography (STL) files that are sliced into machine-readable instructions for precise control.[60]Dye-sublimation printing employs heat to transfer dye from a ribbon onto substrates like plastic or fabric, achieving photo-quality results at resolutions of 300 to 600 dots per inch (dpi), particularly suited for applications such as identification (ID) cards.[61] The process relies on a phase change where solid dye sublimes directly into gas under thermal activation from a print head, allowing the vapor to penetrate the substrate for vibrant, durable images without raised textures.[62][63]Barcode and radio-frequency identification (RFID) printers utilize thermal transfer methods to produce durable labels, embedding inks or ribbons onto synthetic materials for resistance to abrasion and chemicals, with common resolutions like 203 dpi in models from manufacturers such as Zebra.[64] These devices often incorporate RFID encoding alongside barcodes, facilitating inventory and asset tracking in logistics. Solid ink printing, as seen in Xerox Phaser series, involves melting wax-based pellets at approximately 100–140°C to create liquid ink that is ejected onto media, offering vibrant colors and reduced waste compared to liquid toners.[65][66]Emerging technologies extend printing into novel domains, such as nanoscale inkjet systems that deposit conductive graphene inks for fabricating flexible electronics, with research in the 2020s demonstrating viable water-based formulations for inkjet compatibility and device integration.[67] Direct-to-film (DTF) printing, gaining adoption in 2024 for textile applications, applies designs to a polymer film using pigment inks and adhesive powder, followed by heat transfer to fabrics for versatile, high-opacity prints on diverse materials.[68] In 3D printing, biodegradable filaments like PLA—derived from corn starch—enable eco-friendly prototyping, decomposing under industrial composting conditions while maintaining mechanical properties suitable for FDM.[69]As of 2025, further advancements include 4D printing, which builds on 3D techniques by using smart materials that respond to external stimuli (such as temperature, light, or moisture) to change shape or functionality over time, enabling applications in personalized healthcare implants, adaptive manufacturing, and pharmaceuticals.[70][71] Volumetric 3D printing methods like Xolography use intersecting light beams to polymerize entire volumes of resin simultaneously, allowing rapid, high-resolution fabrication of complex structures, including living tissues for bioprinting and objects in microgravity environments.[72][73] Additionally, "printegrated circuits" embed conductive filaments and microcontrollers directly into 3D-printed objects using dual-extrusion printers, creating functional smart devices like sensors and controllers without post-assembly.[74]These specialized printers integrate with computing ecosystems via control languages tailored to their outputs; for instance, G-code directs 3D printer movements in Cartesian coordinates for volumetric builds, contrasting with two-dimensional standards like Printer Command Language (PCL) or PostScript, which rasterize page descriptions for flat media.[75][76]
Classification of Printers
By usage and form factor
Printers are classified based on their primary usage environments and physical form factors, which determine their size, capacity, and suitability for specific settings from individual homes to large-scale industrial operations.Personal and home printers consist of compact desktop models optimized for individual or family use, accommodating standard paper sizes like 8.5 x 11 inches or A4 and typically weighing less than 10 kg. These devices, such as all-in-one inkjet printers, support occasional printing, scanning, and copying tasks with speeds ranging from 5 to 20 pages per minute (ppm).[77] For instance, the Epson Expression Home XP-4105 delivers up to 5.0 ISO ppm in color printing while maintaining a small footprint for home setups.[77] Similarly, the HP DeskJet 2821e achieves 7.5 ppm in black and 5.5 ppm in color, with a 60-sheet input tray suitable for light-duty needs.[78]Office and networked printers, frequently embodied as multifunction printers (MFPs), serve shared environments for workgroups, offering print speeds of 20 to 50 ppm and paper handling capacities exceeding 250 sheets per tray.[79] These units often adopt a larger desktop or floor-standing form factor to accommodate higher volumes, enabling efficient document production in professional settings. The Xerox C325 MFP, for example, prints up to 35 ppm in both color and monochrome, supporting Ethernet for networked access by multiple users.[79]Industrial and large-format printers address demanding production needs, featuring wide-bed designs for roll media up to 24 to 60 inches, with many models weighing over 500 kg to ensure stability during heavy operation.[80] High-volume variants, such as laser-based systems, exceed 100 ppm for bulk output, while plotters handle specialized tasks like blueprint printing. The HP Latex 2700 series, for instance, supports media widths up to 126 inches and roll weights up to 660 lb, ideal for industrial signage and graphics.[80] Inkjet and latex technologies prove especially apt for these applications due to their precision, speed, and ability to handle wide-format media.[81]Portable printers provide mobility for field applications, utilizing battery power and thermal printing mechanisms to produce compact outputs like 2 x 3-inch labels without needing an outlet.[82] These lightweight devices, often under 5 kg, facilitate on-site printing in logistics or fieldwork. The Brother PJ-773, a direct thermal portable unit, reaches speeds up to 8 ppm at 300 x 300 dpi resolution.[82]Across these categories, form factors distinguish desktop configurations for personal and smaller office use—prioritizing spaceefficiency—from robust floor-standing models in industrial contexts, which support greater media loads and durability.[83]
By output type and capability
Printers are classified by output type and capability based on the nature of the produced media, color reproduction, dimensionality, and additional integrated functions. This categorization highlights how printers transform digital data into physical or virtual outputs, ranging from simple text documents to complex three-dimensional objects or multifunctional document handling. Such distinctions influence selection for specific applications, balancing cost, quality, and versatility.Monochrome printers produce output using a single color, typically black toner or ink, optimized for text-heavy documents where high contrast and sharp edges are prioritized. These devices employ electrophotographic processes with a single toner cartridge, resulting in lower operational costs compared to color models due to reduced material expenses and simpler maintenance.[84] In contrast, color printers utilize the CMYK (cyan, magenta, yellow, black) four-color process to generate full-color graphics, images, and photographs by layering subtractive inks or toners on media. This method allows for a wide gamut of colors through precise pigment combinations, enabling vibrant reproductions suitable for marketing materials and visual content.[85] Specialized photo printers extend this capability with 6 to 10 individual ink cartridges, including additional colors like light cyan, light magenta, and photo black, to achieve enhanced tonal gradations and glossy finishes on 4x6-inch photo paper. For instance, models like the Epson SureColor P900 employ UltraChrome PRO10 pigmentinks for archival-quality prints with minimal metamerism.[86]Traditional printers output in two dimensions (2D), depositing ink or toner onto flat media such as paper, film, or fabric to create planar images or text. These devices process raster or vector data to form layers on a surface, limited to surface-level reproduction. In comparison, 3D printers, also known as additive manufacturing systems, build objects layer by layer from digital models, enabling volumetric output up to 300 mm in height for consumer-grade models like the Creality K1 Max, which supports enclosed builds for materials such as PLA or ABS.[87] This dimensionality shift allows for functional prototypes and custom parts, contrasting with 2D printers' focus on visual representation. Briefly referencing extrusion-based methods, 3D printers deposit molten filament in successive layers to form solid structures.Specialized printers target niche outputs beyond general document production. Barcode printers, often thermal direct models, generate durable labels on adhesive media, commonly in 4x6-inch formats for shipping and inventory, using heat-sensitive paper that darkens without ink for quick, cost-effective printing.[88] ID card printers employ dye-sublimation technology to infuse colors directly into PVC cards, producing tamper-resistant badges with photographic quality and embedded security features like holograms.[61] Virtual printers, functioning as software drivers rather than hardware, intercept print jobs to generate digital files such as PDFs without physical output, emulating a printer in the operating system to convert documents from any application into portable formats. Microsoft's built-in Print to PDF driver exemplifies this, allowing seamless file creation from Windows applications.[89]Multifunction printers integrate printing with scanning, copying, and faxing in a single unit, enhancing workflow efficiency by handling multiple document processes. These devices typically feature flatbed scanners for digitizing inputs and automatic document feeders for batch operations, supporting both inbound and outbound fax via analog or digital lines. Additional capabilities include automatic duplexing, which flips media internally for double-sided printing without manual intervention, reducing paper usage by up to 50% in office environments. Envelope feeding mechanisms accommodate varied media sizes, ensuring precise output for correspondence.[90] Such integration is common in models like Xerox all-in-one systems, which combine these functions for small to medium workgroups.[91]
By connectivity and integration
Printers connect to computing systems through various interfaces that enable data transfer, ranging from direct wired connections to wireless and network-based options. These interfaces determine the ease of setup, range, and compatibility in different environments, such as home offices or enterprise networks. Wired connections offer reliable, high-speed links for local use, while wireless options facilitate mobility and shared access across devices.[92]Common wired interfaces include USB and Ethernet. USB 2.0 provides a direct connection at speeds up to 480 Mbps, suitable for personal printers attached to a single computer. USB 3.0 enhances this with SuperSpeed transfer rates of up to 5 Gbps, reducing wait times for large files in modern setups. Ethernet supports local area network (LAN) integration at 10 Mbps, 100 Mbps, or 1000 Mbps (Gigabit), allowing printers to serve multiple users in office environments without relying on a host device.[92][93]Wireless connectivity has become standard, with Wi-Fi and Bluetooth enabling cable-free operation. Wi-Fi 6 (IEEE 802.11ax), introduced in the late 2010s, offers theoretical maximum speeds up to 9.6 Gbps through features like 160 MHz channels and 1024-QAM modulation, improving performance for printers in dense networks with multiple devices. Bluetooth Low Energy (BLE) supports short-range, low-power connections ideal for portable printers, consuming minimal battery while maintaining stable links for mobile printing.[94][95]Protocols standardize communication between printers and devices, ensuring interoperability. The Internet Printing Protocol (IPP), standardized in 1999 by the IETF, enables universal printer discovery and job submission over IP networks, supporting features like status queries and error handling. AirPrint, developed by Apple, allows seamless wireless printing from iOS and macOS devices to compatible printers without additional software. Mopria, an open standard from the Mopria Alliance, facilitates driverless mobile printing from Android devices to certified printers via Wi-Fi or Bluetooth. BLE protocols further extend this for low-energy scenarios in portable applications.[96][97][98][99][95]Integration with broader ecosystems enhances printer functionality beyond basic printing. Cloud services like HP ePrint enable remote printing by emailing documents to a printer's unique address, requiring only an internet connection for access from anywhere. IoT capabilities allow over-the-air firmware updates through manufacturer apps, ensuring printers receive security patches and performance improvements automatically. In operating systems like Windows 11, driverless printing via IPP and Mopria standards simplifies setup, as the OS handles rendering without proprietary drivers, supporting networked office use for shared resources.[100][101][102][103]Security measures protect data transmission in connected printers, especially in shared or remote setups. WPA3 encryption secures Wi-Fi connections against unauthorized access, providing stronger protection for wireless printer networks compared to earlier standards. For hybrid office environments, virtual private networks (VPNs) enable secure remote access to printers, allowing employees to connect over encrypted tunnels to corporate resources without exposing them to public internet risks.[104]
Performance and Features
Print quality and resolution
Print quality in computing printers refers to the fidelity with which the device reproduces images, text, and colors from digital input, primarily measured through resolution, color accuracy, and other visual attributes. Resolution is typically expressed in dots per inch (dpi), indicating the number of ink or toner dots placed horizontally and vertically per inch of output. For standard text and line art on laser printers, a resolution of 600 x 600 dpi provides sufficient sharpness for clear readability without excessive resource use.[105] In contrast, inkjet printers for photographic output often achieve higher resolutions, such as 4800 x 1200 dpi, though this is typically interpolated—meaning software algorithms enhance the native hardware resolution (e.g., around 300 dpi for many Canon models) to simulate finer detail.[106] Epson inkjet printers, for example, have a native resolution of 360 dpi but use variable droplet technology and optimization to reach up to 2880 x 1440 dpi for enhanced photo quality.[107]Printers primarily operate in the CMYK color model, a subtractive system using cyan, magenta, yellow, and black inks or toners to approximate colors by absorbing light on paper, unlike the additive RGB model used for on-screen displays.[108] Digital files in RGB must be converted to CMYK during printing, which can limit the reproducible color range due to the printer's gamut—the subset of colors it can produce. Professional inkjet printers often cover over 90% of the Adobe RGB gamut, enabling vivid reproduction of a wide spectrum, though standard office models may align more closely with sRGB for everyday tasks.[109]Several factors influence print quality beyond raw specifications. Paper absorbency plays a key role, as uncoated papers absorb ink more readily, leading to greater spread and potential blurring compared to coated stocks that control absorption for sharper edges.[110]Ink spread contributes to dot gain, where halftone dots expand upon application, typically increasing by 15-20% in midtone areas (e.g., a 50% tint appearing as 65-70%), darkening the image and reducing contrast.[111] Color accuracy is quantified using Delta E (ΔE), a metric for perceptual color differences; values below 2 are generally imperceptible to the human eye, ensuring high-fidelity output.[109]Standardized testing evaluates these attributes for consistency. The ISO 12647 series defines parameters for color reproduction, including dot gain targets and solid density, to benchmark print processes across devices.[112] For sharpness and perceived resolution, ISO/IEC 29112 provides methods to measure edge acuity and detail rendition in printed images.[113] Photo quality further varies by media type; glossy papers (200-300 gsm) enhance vibrancy and contrast for high-impact images but can introduce glare, while matte finishes (also 200-300 gsm) reduce reflections for a subtler, artifact-free appearance suitable for viewing under varied lighting.[114]
Speed and efficiency
Printer speed is typically measured in pages per minute (ppm), with modern laser printers achieving 20 to 60 ppm in draft or economy modes for text documents, while inkjet models range from 5 to 20 ppm under similar conditions.[115][116] In high-quality modes, speeds drop significantly to 5 to 15 ppm across both types to allow for enhanced detail processing. For photographic output, dye-sublimation printers can produce up to 100 to 300 4x6-inch images per hour, enabling efficient production for photo labs and event printing.[117] Thermal printers, by contrast, face inherent speed limits due to heating cycles, often capping at 10 to 20 ppm for labels and receipts.[118]Operational modes further influence efficiency, with draft settings prioritizing speed over resolution for quick proofs, whereas best-quality modes extend processing time for professional outputs. First-page-out time, the delay from job initiation to the first sheet emerging, averages 5 to 15 seconds in contemporary models, minimizing workflow interruptions in office environments.[83][119] Duty cycles, representing the maximum recommended monthly print volume, reach up to 50,000 pages for mid-range office laser printers, ensuring reliability under heavy use without excessive wear.[120]Efficiency extends to resource management, where power consumption during printing ranges from 10 watts for compact inkjets to 500 watts for high-volume lasers, with Energy Star-certified models maintaining standby power below 1 watt to reduce energy costs.[121] Optimizations like automatic duplex printing halve paper usage by printing on both sides, achieving up to 50% savings in material costs for document-heavy operations.[122]Collation features automatically organize multi-page jobs into sets, streamlining assembly without manual intervention.
Cost and economics
The cost of acquiring a printer varies significantly by type and intended use. Home inkjet printers generally range from $50 to $200, making them accessible for personal or light-duty applications.[123] Office laser printers, designed for higher-volume professional environments, typically cost between $500 and $5,000, reflecting their durability and efficiency features.[124] Industrial printers, used in production settings for large-scale or specialized output, start at $10,000 and can exceed this substantially depending on capacity and technology.[125]Operational costs are dominated by consumables such as ink and toner, which directly impact per-page expenses. For standard laser printers, monochrome costs typically range from 0.02 to 0.05 USD per page, while color costs 0.05 to 0.10 USD. Traditional inkjet printers have higher costs, with monochrome around 0.06 to 0.10 USD and color 0.08 to 0.15 USD per page, depending on cartridge yields and pricing as of 2025.[126][127] Tank-based systems like the Epson EcoTank achieve even lower rates, often around 0.001 USD per page for both color and monochrome, due to high-yield refillable ink bottles.The total cost of ownership (TCO) for a printer encompasses the initial purchase price plus ongoing expenses from consumables and maintenance, calculated as initial cost + (annual pages printed × cost per page) + service fees. For high-volume printing, laser printers often exhibit a lower TCO than traditional inkjets, owing to cheaper toner and reduced replacement frequency.[128]Printer economics frequently follow the razor-and-blades model, where hardware is sold at low margins to drive recurring revenue from profitable supplies like ink and toner.[129] In 2025, subscription services such as HP Instant Ink exemplify evolving trends, offering ink delivery based on usage with effective per-page costs as low as 0.05 USD for higher-volume plans, reducing upfront supply burdens while ensuring steady manufacturer income.[130]
Security and other attributes
Printer security encompasses several mechanisms to protect sensitive data during printing and prevent unauthorized access. One notable feature is printer steganography, where color laser printers embed tiny yellow dots—measuring about one millimeter in diameter—on printed pages to encode the printer's serial number, date, and time of printing.[131] This tracking technology, implemented since the early 2000s by manufacturers like Xerox and Canon in collaboration with government agencies, aids in forensic identification but raises privacy concerns for users printing confidential documents.[132] To mitigate unauthorized printing, secure print functionality allows jobs to be held in the printer's memory until released via a personal identification number (PIN) or password at the device, ensuring physical presence is required for output.[133][134]Firmwareencryption further enhances protection by encrypting data on hard disks, solid-state drives, or embedded multimedia cards (eMMC), with keys generated randomly upon device startup and stored in secure memory to prevent data recovery from decommissioned units.[135][136]Privacy risks in printers have been highlighted by vulnerabilities such as buffer overflows, which can allow remote attackers to execute arbitrary code or cause denial-of-service conditions. For instance, in the 2020s, multiple common vulnerabilities and exposures (CVEs) affected printer models, including Xerox devices vulnerable to IPP service overflows (CVE-2019-13165) and Canon laser printers susceptible to WSD protocol exploits (CVE-2024-12647 through CVE-2024-12649).[137][138] Mitigation strategies include network-level authentication protocols like IEEE 802.1X, which requires printers to authenticate via certificates or MAC addresses before granting port access, thereby restricting unauthorized devices on wired or wireless networks.[139]Printers utilize standardized page description languages (PDLs) to interpret and render print jobs accurately across devices. Hewlett-Packard's Printer Command Language (PCL), first introduced in 1984, supports both bitmap and vector graphics, enabling efficient rendering of text, images, and layouts in versions like PCL 5 and PCL 6, which are widely used in office environments for their compatibility and speed.[140] Adobe's PostScript, developed in 1982, is a stack-based programming language that describes page content independently of the output device, incorporating over 35 built-in fonts and facilitating complex graphics in desktop publishing; it remains prevalent in professional printing workflows.[141] Many modern printers also support direct PDF printing, allowing Adobe PDF files (versions 1.3 to 1.7) to be processed natively without intermediate conversion, provided a PostScript 3 unit or equivalent emulation is installed, which streamlines workflows in enterprise settings.[142][143]Beyond security and languages, printers exhibit various attributes influencing user experience and environmental footprint. Noise levels typically range from 40 to 60 decibels (dB) during operation, comparable to a quiet conversation, with laser printers often louder at 50-55 dB due to mechanical components, while inkjets may hover around 45 dB; standby modes are quieter at 25-35 dB. Sustainability efforts include the use of recycled plastics in casings and components—such as up to 25% post-consumer recycled content in some models—and compliance with e-waste directives like the EU's Waste Electrical and Electronic Equipment (WEEE) Directive, which mandates separate collection and recycling targets, with updates effective in 2025 requiring enhanced producer responsibility for items like printers to minimize landfill disposal.[144] Accessibility features extend to braille embossers, specialized printers that use solenoids to raise dots on paper for tactile reading, supporting single- or double-sided output at speeds up to 120 characters per second and integrating with screen readers for blind or low-vision users to produce documents from digital text.[145]
Industry and Market
Major manufacturers
HP Inc. has been a dominant force in the printer industry since introducing the LaserJet in 1984, the world's first commercially successful desktop laser printer, which revolutionized office printing with its high-quality, quiet output using electrophotographic technology.[14][146] The company followed this with the DeskJet in 1988, the first mass-market inkjet printer, featuring a disposable printhead for consistent plain-paper printing at speeds up to 2 pages per minute.[17][147] By 2025, HP emphasizes PageWide inkjet technology, which employs stationary page-wide printheads to achieve offset-quality speeds exceeding 70 pages per minute while reducing energy use compared to traditional laser systems.[148][149]Canon leads in developing inkjet and laser printing engines, beginning with its foundational Bubble Jet thermal inkjet technology patented in 1977, which uses heat to vaporize ink for precise droplet ejection.[150] The company's laser engines power high-speed monochrome and color devices with resolutions up to 1200 dpi, enabling efficient document production for offices and enterprises.[151] Canon's imagePROGRAF series targets professional graphics applications, offering large-format inkjet printers with 12-color LUCIA PRO II inks for archival-quality prints up to 60 inches wide and resolutions of 2400 x 1200 dpi.[152][153]Epson pioneered piezoelectric inkjet printing with its Micro Piezo technology, which employs thin-film piezoelectric actuators to control ink droplet volume and shape for superior precision and durability, lasting the printer's lifetime without replacement.[154][155] The EcoTank lineup features refillable supertank ink reservoirs, providing up to 7,500 black or 6,000 color pages per bottle set to minimize cartridge costs for home and small office use.[156]Epson's PrecisionCore printhead technology, capable of 40 million dots per second, extends to 3D printing innovations like direct-to-shape systems introduced in 2025, enabling 600 dpi printing on curved surfaces for industrial applications.[157][158]Brother focuses on cost-effective laser printers and multifunction printers (MFPs) tailored for small and medium-sized businesses, with models like the MFC-L series offering print speeds up to 36 pages per minute and toner yields exceeding 3,000 pages at yields as low as 1.2 cents per black page.[159] These devices incorporate mobile-centric designs, supporting wireless printing via AirPrint and Brother iPrint&Scan apps for seamless smartphone integration in SMB environments.[160][161]Among other key players, Xerox developed solid ink technology, using solid wax-based color sticks that melt into liquid for phase-change printing, delivering vibrant output on diverse media with up to 90% less waste than liquid toners and speeds of 55 pages per minute.[162][163]Ricoh specializes in production printers, such as the Pro C5400S series, which use VCSEL laser engines for inline finishing and output up to 130 color pages per minute on substrates up to 400 gsm, streamlining high-volume commercial workflows.[164][165]Zebra Technologies excels in label printers for barcode and RFID tagging, with industrial models like the ZT510 series providing durable thermal transfer printing at 14 inches per second on synthetic labels for logistics and healthcare.[166] HP bolstered its printer portfolio through 2010s acquisitions, notably purchasing Samsung's printer division in 2017 for $1.05 billion to gain multifunction laser expertise and expand in emerging markets.[167]
Market dynamics and future outlook
The global printer market in 2025 is estimated at approximately $53-65 billion, reflecting steady recovery from pandemic disruptions and adaptation to digital workflows. Inkjet printers account for around 52% of the market share, driven by their affordability and versatility for home and small office use, while laser printers hold about 37%, favored for high-volume professional applications. Specialized printers, including multifunction and large-format models, comprise the remaining portion, catering to niche sectors like packaging and signage. Among major manufacturers, HP commands approximately 30% of the market through its dominance in inkjet and laser segments, followed by Canon at 21%, with Epson and Brother each securing about 8-10% via innovations in eco-friendly and compact devices.[168][169][170]Key market drivers include the rise of hybrid work environments, which have accelerated demand for multifunction printers (MFPs) capable of scanning, copying, and printing with integrated connectivity, projecting a 6% compound annual growth rate (CAGR) through 2030. The digital shift toward paperless offices has tempered growth in traditional 2D printing but boosted specialized segments, particularly 3D printing, expected to expand at a 17-20% CAGR to reach $35-40 billion by 2030 due to applications in prototyping and customization. Additionally, sustainability initiatives, such as Epson's EcoTank systems using refillable ink tanks, are gaining traction to reduce cartridge waste and appeal to environmentally conscious consumers.[171][172][173]Challenges persist in supply chain vulnerabilities, with ink and toner shortages in the early 2020s—exacerbated by global logistics issues—leading to production delays and price volatility for consumers and businesses. E-waste from obsolete printers contributes to broader electronic waste streams, with global e-waste generation reaching 62 million metric tons in 2022 and projected to rise, underscoring the need for better recycling amid an estimated 1 billion annual units of discarded consumer electronics. Regulatory efforts, such as the EU's 2025 e-waste recycling targets requiring 85% collection rates for large equipment, are pushing manufacturers toward more sustainable designs. Opportunities arise in sustainable technologies, including biodegradable inks and materials, which are fostering a niche market valued at over $2 billion and growing to support circular economy practices.[174][175][176][177][178]Looking ahead, the printer market is forecasted to reach $70-85 billion by 2030, propelled by a 4-5% overall CAGR amid integration of advanced features like AI for predictive maintenance and automated ink reordering, alongside cloud-based services for seamless remote access. Enhanced 5G connectivity is enabling efficient management of printer fleets in distributed work settings, reducing latency in mobile printing. The Asia-Pacific region is poised to hold about 50% of global market share by 2030, driven by rapid urbanization, SME expansion, and manufacturing hubs in China and India.[168][179][180][181]
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