Printed Envelopes in Northfield Mn
Digital printing in Minnesota has been a door opener for many businesses. Because printers sell the same thing as everyone else, everyone tries to claim that their service, quality and price are better than others. For this reason, every printer has to find something that would separate them from everyone else. And some business owners find that they have increased productivity after using digital technology and short run processes. Somehow, these gains can be credited to a combination of better pricing and more efficient press performance. Let’s say you have greeting cards that need to be printed. Obsolete inventory through the use of short run digital press can be eliminated.
Printed Envelopes in Northfield Mn
This is because with this technology you can print only the needed cards, thus, resulting to orders printed in the exact quantity required. But just the same this kind of printing system is not for everyone. There are risks and changes that need to be dealt with. Nevertheless, the printing industry will continue to change and improve in the years to come. Thus, all business owners and companies have to do is to determine whether this certain printing technique is what they need.
Digital Printing Press: An Update Banner Printing
(Redirected from Indigo Digital Press) HP Indigo building, Nes Ziona, Israel HP Indigo Division, is a company that was first developed and popularized as an Israeli company named Indigo Digital Press that was bought by Hewlett-Packard. It develops, manufactures and markets digital printing solutions, including printing presses, proprietary consumables and workflow. Founded in 1977, it was an independent company until it was acquired by HP in 2001. They have offices around the world, with headquarters in Nes Ziona, Israel. Customers of HP Indigo solutions include commercial printers, photo specialty printers, and label and packaging converters to print applications such as marketing collateral, photo albums, direct mail, labels, folding cartons, flexible packaging, books, manuals, and specialty jobs. The ability of digital presses to print without plates enables the use of variable data such as text or images, such as in personalized direct marketing applications, or in photo albums, which are usually printed in copies of one. Digital presses also make short-run and just-in-time printing cost-effective. In this way, digital presses have changed the economic models for print in a wide variety of market segments, cutting down on supply chain costs and simplifying the creation of campaigns that reach consumers in more creative, personalized ways. The name Indigo comes from a company formed by Benny Landa in 1977. Landa, known as the father of digital offset color printing, was born in Poland to post-World War II Jewish refugee parents, who later immigrated to Edmonton, Alberta, Canada. Landa's interest in printing goes back to the time he worked as a child in his father's photo shop. His father purchased a cigar store that had a small photo studio in the back which he developed, using his skills as a carpenter, into his own portrait studio. While a student in London, Landa got a job at Commercial Aid Printing Services (CAPS), a company offering printing services and microfilm solutions. Landa was instrumental in developing a solution that won the company a contract with Rolls Royce and was appointed as Head of R&D. However, CAPS lacked manufacturing capital and went into receivership in 1969. In 1971 he joined Gerald Frankel, the owner of CAPS, and founded a new company - Imaging Technology (Imtec). Landa led Imtec’s R&D activities and invented the company’s core imaging technology. While researching liquid toners at Imtec, he worked on a method of high-speed image development that would later lead to the invention of ElectroInk. At the start of the 1990s Indigo moved from a primarily research-driven business into a full-scale printing equipment manufacturing company. The company's first product would be a digital plotter/duplicator, bringing the tiny company (its 1991 sales totaled less than US$5 million, generating a profit of $440,000) head to head with such industry giants as Xerox and Canon. In 1993 Indigo launched the E-Print 1000 at IPEX trade show. The E-Print 1000 eliminated the expense and labor of the plate-printing setup process, printing directly from a computer file, and enabled inexpensive short-run color printing. Images not only could be readily changed, they could be changed from page to page, requiring neither additional setup or pauses in the print run. Instead of printing to metal plates, the E-Print created a latent image on the Photo Imaging Plate or PIP through the use of an electrostatic charge. This charged area would then attract the charged ElectroInk, which would in turn be transferred to the ITM or blanket, and then again transfer from the blanket to the paper or other substrate. Because 100% of the ink transfers from PIP to blanket to substrate, a different image and color could be printed with each rotation of the press. At the same time, Indigo's ElectroInk-based color inks offered print quality rivaling that of traditional printing processes. Almost 20 years later, and despite the numerous technological improvements, Indigo presses are still based on this core technology. In 1994 Indigo had an initial public offering on the NASDAQ stock exchange, selling 52 million shares at $20 per share and raising $100 million. The offering reduced Landa's personal holding in Indigo to 70 percent. As the stock continued to climb, the following year, Landa's paper worth reached some $2 billion by 1995. At the drupa trade show in 1995 Indigo launched another product: the Omnius press. Whereas E-Print focused on medium-volume single-sheet printing, Omnius brought digital printing to a variety of surfaces, including plastic, cardboard, film, and, especially, cans, bottles, and other packaging surfaces. Omnius was the precursor of today's portfolio of Indigo's labels and packaging presses. At the end of 1995, Indigo sales did not reach the expected levels, and the company found itself overstaffed. Despite a strong rise in revenues to $165 million, the company posted its fourth year of losses, of about $40 million. George Soros however still believed in the company’s potential and increased his investment to 30 percent of Indigo's shares by 1997. By 1998 the company improved its financial performance and revenues passed the $200 million mark for the first time. Hewlett-Packard offices in Nes Ziona In 2000 the Hewlett-Packard company made a $100m investment in Indigo, buying 14.8 million of Indigo's common shares, which represented 13.4 percent of the company's outstanding shares. On September 6, 2001, HP announced that it would acquire the remaining outstanding shares of Indigo Indigo N.V. (NASDAQ: INDG) for approximately $629 million in HP common stock and a potential future cash payment of up to $253 million contingent upon Indigo's achievement of long-term revenue goals, for an aggregate potential payment of up to $882 million.  In the following years, HP continued to invest in Israel-based graphic arts companies, acquiring Scitex Vision in 2005 and Nur Macroprinters in 2007. Other employees of HP in Israel (which includes not only employees of the Indigo division, but also of Scitex and Israeli's divisions of HP Labs, made it the second-largest foreign employer after Intel. Under the ownership of HP, Indigo developed and grew to become a world leader in the digital print industry. In 2002 they announced the first product manufactured jointly with HP: the HP Indigo 5000, and their second generation of products (known internally as "series 2") was born. Other products belonging to these series were the roll-fed ws4000 series. At drupa 2008 Indigo announced the Indigo 7000 digital press, with over 70% higher productivity over series 2. This product further pushed the break-even point versus offset lithography and enabled more pages to be economically viable on Indigo. Other presses unveiled at drupa included the double engine Indigo W7200 and the new derivative for labels, the Indigo WS6000. In August 2009 HP announced they had reached 5,000 HP Indigo digital presses in operation around the world. The company is ranked No. 1 in the US high-volume digital press market and, according to HP officials, has a 75% share of the world market for digital commercial photo printing. In March 2012 HP Indigo unveiled the Indigo 10000 B2/29" digital press and released it to market a year later. By March 2016, there were over 200 Indigo 10000 customer installations in over 20 countries. In September 2013, Indigo claimed dominance of the narrow label market, with General Manager Alon Bar-Shany calling the Indigo WS6600 press "the best-selling solution in the narrow web industry, not just in digital printing, (but) narrow overall."  In 2014, HP Indigo marked the launch of the new 20000 and 30000 digital presses, aimed at the packaging markets. The presses target flexible packaging converters, label converters and folding carton establishments. In 2016 Indigo announced a new portfolio based on innovation on four core pillars of their technology: quality, color, applications and productivity. They also announced PrintOS, a cloud-based platform to help customers. HP Indigo uses a proprietary, patented technology and a business model that sells both presses and their consumables, as well as services. The presses are assembled in a dedicated facility in HP's Kiryat Gat campus, and the inks are manufactured in both Kiryat Gat and TUAS, Singapore. Indigo has over 4500 customers in 120 countries around the world. They include some of the largest names in print world, including Cimpress and Consolidated Graphics (now part of RR Donnelley) but also a widevariety of small and medium-sized print service providers and labels and packaging converters. According to Indigo GM Alon Bar-Shany, volume printed on Indigo presses grew by over 50% from 2012 to 2016, reaching an estimated 30 B pages. The year 2005 marked the creation of Dscoop, the independent user's group of Indigo and HP Graphic Arts solutions. By 2015 it reached over 7000 users today, including owners and technical personnel. Dscoop membership is free of charge for HP Graphic Arts users throughout the Americas, Europe, the Middle East and Africa, Asia Pacific and Japan. There are several families of HP Indigo presses, which can be broadly grouped by the type of paper-handling mechanism they work with: Sheetfed (or cut-sheet) or Webfed (or roll-fed). Sheetfed presses print on sheets, have a feeder system consisting of drawers and/or a pallet of paper, and print on both sides of the paper (duplex print/perfecter), printed sheets are collected in a stacker mainly for paper printing. Examples of sheetfed presses include the HP Indigo 7900, the HP Indigo 10000 and the new HP Indigo 12000. Webfed presses print on rolls, often referred to as a web the feeder system (unwinder) feeds the paper through continuously in most cases, print on one side of the substrate (simplex) printed rolls can be collected on a rewinder or cut into sheets (sheeter). Examples of webfed presses are the HP Indigo WS6800 narrow format press for labels and flexible packaging, the Indigo 20000 digital press, and the Indigo W7250 for books, photo and other commercial applications. The launch of the HP Indigo 10000 digital press in 2012 marked the first time the company embarked on a platform that supports a paper size beyond A3. With the B2/29.5" paper format, they aim to increase the productivity and application range of traditional print service providers. In 2014 two new products based in the same type of engine/format were released, the Indigo 20000 and the Indigo 30000, aimed at the flexible packaging and folding-cartons markets, respectively. In 2016, Indigo introduced the 80/minutes per meter roll-fed 80000 press for label production, as well as new models of its sheetfed presses: the 12000, 7900 and 5900. The also announced the B1 roll-fed Indigo 50000, which is scheduled for release in 2017. In addition, the announced new solutions for packaging post-print under the Pack Ready umbrella, and demonstrated a concept for digital combination printing for labels. Each Indigo press has up to 7 color stations, which can use cyan, magenta, yellow, black and a variety of special and spot color inks, such as white, silver, UV red and transparent. HP provides the option for users to mix their own ink colors to match Pantone references. This is common with non-digital offset litho presses, and is one of the features that distinguishes the HP Indigo process. "Off-press" colors are mixed from 11 color (from the 15 original) Pantone spectrum at an offline, ink mixing station. Users can also order special pre-mixed colors from HP Indigo, for example fluorescent pink. HP Indigo presses are available in configurations supporting four, five, six or seven colors. At drupa 2008, Indigo unveiled a new workflow strategy for their portfolio called HP SmartStream, based on their own development and on partnerships with other industry vendors. Among the announcements was a [web-to-print] product in partnership with Press-Sense (later bought by Bitstream makers of Pageflex.) They also released new versions of their Digital Front Ends (DFEs). Today, their SmartStream workflow portfolio is based on both their own products, as well as partnerships with other graphic arts vendors in fields such as job creation, pre-press, variable data printing and finishing. In 2004 HP made a 100 million shekel investment in a new production site in Kiryat Gat, Israel. The factory is responsible for manufacturing HP Indigo ElectroInk. There is a sister facility in Singapore that also manufactures Indigo ElectroInk. In 2007 an adjacent hardware center was opened in Kiryat Gat. This facility assembles frames, feeders, and other components with imaging engines into finished presses, and also serves as the site for manufacturing other operator-replaceable consumables, such as the blanket. In late 2012, HP Indigo inaugurated a second ink plant in Kiryat Gat, which will focus on the manufacturing of ElectroInk for the new family of presses: the HP Indigo 10000, Indigo 20000 and Indigo 30000 digital presses. This 118,000 square feet facility is reported to be the first building in the country and the first HP manufacturing facility worldwide designed to meet the LEED Silver environmental standard. Early incarnations of the press (Series 1 engines) were prone to banding and ink adhesion problems. However newer models have corrected most of these issues.
Digital Color Prints vs Color Copies(Redirected from Megapixel) This example shows an image with a portion greatly enlarged, in which the individual pixels are rendered as small squares and can easily be seen. A photograph of sub-pixel display elements on a laptop's LCD screen In digital imaging, a pixel, pel, dots, or picture element is a physical point in a raster image, or the smallest addressable element in an all points addressable display device; so it is the smallest controllable element of a picture represented on the screen. The address of a pixel corresponds to its physical coordinates. LCD pixels are manufactured in a two-dimensional grid, and are often represented using dots or squares, but CRT pixels correspond to their timing mechanisms . Each pixel is a sample of an original image; more samples typically provide more accurate representations of the original. The intensity of each pixel is variable. In color imaging systems, a color is typically represented by three or four component intensities such as red, green, and blue, or cyan, magenta, yellow, and black. In some contexts (such as descriptions of camera sensors), the term pixel is used to refer to a single scalar element of a multi-component representation (more precisely called a photosite in the camera sensor context, although the neologism sensel is sometimes used to describe the elements of a digital camera's sensor), while in yet other contexts the term may be used to refer to the set of component intensities for a spatial position. Drawing a distinction between pixels, photosites, and samples may reduce confusion when describing color systems that use chroma subsampling or cameras that use Bayer filter to produce color components via upsampling. The word pixel is based on a contraction of pix (from word "pictures", where it is shortened to "pics", and "cs" in "pics" sounds like "x") and el (for "element"); similar formations with 'el' include the words voxel and texel. The word "pixel" was first published in 1965 by Frederic C. Billingsley of JPL, to describe the picture elements of video images from space probes to the Moon and Mars. Billingsley had learned the word from Keith E. McFarland, at the Link Division of General Precision in Palo Alto, who in turn said he did not know where it originated. McFarland said simply it was "in use at the time" (circa 1963). The word is a combination of pix, for picture, and element. The word pix appeared in Variety magazine headlines in 1932, as an abbreviation for the word pictures, in reference to movies. By 1938, "pix" was being used in reference to still pictures by photojournalists. The concept of a "picture element" dates to the earliest days of television, for example as "Bildpunkt" (the German word for pixel, literally 'picture point') in the 1888 German patent of Paul Nipkow. According to various etymologies, the earliest publication of the term picture element itself was in Wireless World magazine in 1927, though it had been used earlier in various U.S. patents filed as early as 1911. Some authors explain pixel as picture cell, as early as 1972. In graphics and in image and video processing, pel is often used instead of pixel. For example, IBM used it in their Technical Reference for the original PC. Pixilation, spelled with a second i, is an unrelated filmmaking technique that dates to the beginnings of cinema, in which live actors are posed frame by frame and photographed to create stop-motion animation. An archaic British word meaning "possession by spirits (pixies)," the term has been used to describe the animation process since the early 1950s; various animators, including Norman McLaren and Grant Munro, are credited with popularizing it. A pixel does not need to be rendered as a small square. This image shows alternative ways of reconstructing an image from a set of pixel values, using dots, lines, or smooth filtering. A pixel is generally thought of as the smallest single component of a digital image. However, the definition is highly context-sensitive. For example, there can be "printed pixels" in a page, or pixels carried by electronic signals, or represented by digital values, or pixels on a display device, or pixels in a digital camera (photosensor elements). This list is not exhaustive and, depending on context, synonyms include pel, sample, byte, bit, dot, and spot. Pixels can be used as a unit of measure such as: 2400 pixels per inch, 640 pixels per line, or spaced 10 pixels apart. The measures dots per inch (dpi) and pixels per inch (ppi) are sometimes used interchangeably, but have distinct meanings, especially for printer devices, where dpi is a measure of the printer's density of dot (e.g. ink droplet) placement. For example, a high-quality photographic image may be printed with 600 ppi on a 1200 dpi inkjet printer. Even higher dpi numbers, such as the 4800 dpi quoted by printer manufacturers since 2002, do not mean much in terms of achievable resolution. The more pixels used to represent an image, the closer the result can resemble the original. The number of pixels in an image is sometimes called the resolution, though resolution has a more specific definition. Pixel counts can be expressed as a single number, as in a "three-megapixel" digital camera, which has a nominal three million pixels, or as a pair of numbers, as in a "640 by 480 display", which has 640 pixels from side to side and 480 from top to bottom (as in a VGA display), and therefore has a total number of 640×480 = 307,200 pixels or 0.3 megapixels. The pixels, or color samples, that form a digitized image (such as a JPEG file used on a web page) may or may not be in one-to-one correspondence with screen pixels, depending on how a computer displays an image. In computing, an image composed of pixels is known as a bitmapped image or a raster image. The word raster originates from television scanning patterns, and has been widely used to describe similar halftone printing and storage techniques. For convenience, pixels are normally arranged in a regular two-dimensional grid. By using this arrangement, many common operations can be implemented by uniformly applying the same operation to each pixel independently. Other arrangements of pixels are possible, with some sampling patterns even changing the shape (or kernel) of each pixel across the image. For this reason, care must be taken when acquiring an image on one device and displaying it on another, or when converting image data from one pixel format to another. For example: Text rendered using ClearType Computers can use pixels to display an image, often an abstract image that represents a GUI. The resolution of this image is called the display resolution and is determined by the video card of the computer. LCD monitors also use pixels to display an image, and have a native resolution. Each pixel is made up of triads, with the number of these triads determining the native resolution. On some CRT monitors, the beam sweep rate may be fixed, resulting in a fixed native resolution. Most CRT monitors do not have a fixed beam sweep rate, meaning they do not have a native resolution at all - instead they have a set of resolutions that are equally well supported. To produce the sharpest images possible on an LCD, the user must ensure the display resolution of the computer matches the native resolution of the monitor. The pixel scale used in astronomy is the angular distance between two objects on the sky that fall one pixel apart on the detector (CCD or infrared chip). The scale s measured in radians is the ratio of the pixel spacing p and focal length f of the preceding optics, s=p/f. (The focal length is the product of the focal ratio by the diameter of the associated lens or mirror.) Because p is usually expressed in units of arcseconds per pixel, because 1 radian equals 180/π*3600≈206,265 arcseconds, and because diameters are often given in millimeters and pixel sizes in micrometers which yields another factor of 1,000, the formula is often quoted as s=206p/f. Main article: Color depth The number of distinct colors that can be represented by a pixel depends on the number of bits per pixel (bpp). A 1 bpp image uses 1-bit for each pixel, so each pixel can be either on or off. Each additional bit doubles the number of colors available, so a 2 bpp image can have 4 colors, and a 3 bpp image can have 8 colors: ... For color depths of 15 or more bits per pixel, the depth is normally the sum of the bits allocated to each of the red, green, and blue components. Highcolor, usually meaning 16 bpp, normally has five bits for red and blue, and six bits for green, as the human eye is more sensitive to errors in green than in the other two primary colors. For applications involving transparency, the 16 bits may be divided into five bits each of red, green, and blue, with one bit left for transparency. A 24-bit depth allows 8 bits per component. On some systems, 32-bit depth is available: this means that each 24-bit pixel has an extra 8 bits to describe its opacity (for purposes of combining with another image). Geometry of color elements of various CRT and LCD displays; phosphor dots in a color CRTs display (top row) bear no relation to pixels or subpixels. Many display and image-acquisition systems are, for various reasons, not capable of displaying or sensing the different color channels at the same site. Therefore, the pixel grid is divided into single-color regions that contribute to the displayed or sensed color when viewed at a distance. In some displays, such as LCD, LED, and plasma displays, these single-color regions are separately addressable elements, which have come to be known as subpixels. For example, LCDs typically divide each pixel vertically into three subpixels. When the square pixel is divided into three subpixels, each subpixel is necessarily rectangular. In display industry terminology, subpixels are often referred to as pixels, as they are the basic addressable elements in a viewpoint of hardware, and hence pixel circuits rather than subpixel circuits is used. Most digital camera image sensors use single-color sensor regions, for example using the Bayer filter pattern, and in the camera industry these are known as pixels just like in the display industry, not subpixels. For systems with subpixels, two different approaches can be taken: This latter approach, referred to as subpixel rendering, uses knowledge of pixel geometry to manipulate the three colored subpixels separately, producing an increase in the apparent resolution of color displays. While CRT displays use red-green-blue-masked phosphor areas, dictated by a mesh grid called the shadow mask, it would require a difficult calibration step to be aligned with the displayed pixel raster, and so CRTs do not currently use subpixel rendering. The concept of subpixels is related to samples. Diagram of common sensor resolutions of digital cameras including megapixel values Marking on a camera phone that has about 2 million effective pixels. A megapixel (MP) is a million pixels; the term is used not only for the number of pixels in an image, but also to express the number of image sensor elements of digital cameras or the number of display elements of digital displays. For example, a camera that makes a 2048×1536 pixel image (3,145,728 finished image pixels) typically uses a few extra rows and columns of sensor elements and is commonly said to have "3.2 megapixels" or "3.4 megapixels", depending on whether the number reported is the "effective" or the "total" pixel count. Digital cameras use photosensitive electronics, either charge-coupled device (CCD) or complementary metal–oxide–semiconductor (CMOS) image sensors, consisting of a large number of single sensor elements, each of which records a measured intensity level. In most digital cameras, the sensor array is covered with a patterned color filter mosaic having red, green, and blue regions in the Bayer filter arrangement, so that each sensor element can record the intensity of a single primary color of light. The camera interpolates the color information of neighboring sensor elements, through a process called demosaicing, to create the final image. These sensor elements are often called "pixels", even though they only record 1 channel (only red, or green, or blue) of the final color image. Thus, two of the three color channels for each sensor must be interpolated and a so-called N-megapixel camera that produces an N-megapixel image provides only one-third of the information that an image of the same size could get from a scanner. Thus, certain color contrasts may look fuzzier than others, depending on the allocation of the primary colors (green has twice as many elements as red or blue in the Bayer arrangement). DxO Labs invented the Perceptual MegaPixel (P-MPix) to measure the sharpness that a camera produces when paired to a particular lens – as opposed to the MP a manufacturer states for a camera product which is based only on the camera's sensor. The new P-MPix claims to be a more accurate and relevant value for photographers to consider when weighing-up camera sharpness. As of mid-2013, the Sigma 35mm F1.4 DG HSM mounted on a Nikon D800 has the highest measured P-MPix. However, with a value of 23 MP, it still wipes-off more than one-third of the D800's 36.3 MP sensor. A camera with a full-frame image sensor, and a camera with an APS-C image sensor, may have the same pixel count (for example, 16 MP), but the full-frame camera may allow better dynamic range, less noise, and improved low-light shooting performance than an APS-C camera. This is because the full-frame camera has a larger image sensor than the APS-C camera, therefore more information can be captured per pixel. A full-frame camera that shoots photographs at 36 megapixels has roughly the same pixel size as an APS-C camera that shoots at 16 megapixels. One new method to add Megapixels has been introduced in a Micro Four Thirds System camera which only uses 16MP sensor, but can produce 64MP RAW (40MP JPEG) by expose-shift-expose-shift the sensor a half pixel each time to both directions. Using a tripod to take level multi-shots within an instance, the multiple 16MP images are then generated into a unified 64MP image.
Digital color printing • carbonless forms • Large format printing • Minnesota