In Storage, Innovation Has Been Key To Providing Quality And Choice.The 1990s-those were the Li days. It's impossible to look back at the past decade of technological innovation in storage media and not be overwhelmed o·ver·whelm tr.v. o·ver·whelmed, o·ver·whelm·ing, o·ver·whelms 1. To surge over and submerge; engulf: waves overwhelming the rocky shoreline. 2. a. by just how far we have progressed. In 1990, a PC with Intel's 386 chip and a 100MB hard drive was considered a powerhouse A fourth-generation language from Cognos that was introduced in the late 1970s for midrange computers. It supports both character-oriented, terminal-based applications as well as Windows clients. Applications developed under PowerHouse can be imported into Cognos' Axiant client/server environment. . And, in those days, most people backed up with cassette tapes and saved and exchanged files on 5.25inch floppy disks (that were actually floppy) with storage capacities of 360 kilobytes and 1.2 megabytes. That may sound miniscule min·is·cule adj. Variant of minuscule. Adj. 1. miniscule - very small; "a minuscule kitchen"; "a minuscule amount of rain fell" minuscule by today's standards, but given the size of the data files created by that generation's programs, one could fit an entire file drawer on one floppy. Who could have imagined back then that we would eventually need storage media that could hold more data? In the early 1990s the 3.5inch floppy disk was the most popular product for desktop storage. The 3.5-inch floppy quickly became a hot commodity that boasted a storage capacity of 1.44MB. For the following few years, the Years, The the seven decades of Eleanor Pargiter’s life. [Br. Lit.: Benét, 1109] See : Time 3.5inch 1.44MB floppy remained the singular option-the standard-for desktop storage. However, by the end of 1992, industry hardware and media manufacturers realized that the removable data storage category had to be expanded as file size increased. Consumers, small organizations, and large enterprises, with differing requirements and multiple applications, were computerizing more of their activities and vital business functions. And, as a result, something became crystal clear- the need for choice among formats that offered a range of transfer rates and storage capacities. With this choice of storage formats from which to choose, end users began to face a number of questions: * What file sizes and file types will be stored? 8 Who will need access to this data? * How fast do we need to access this data? * How long do we need to store this data? * How much can we afford for storage? These questions look familiar, don't they? These are the same questions that end users must ask themselves today as they survey the range of storage solutions available to them. For a better picture of today's growing storage capacity needs, consider the following representative samples of storage capacity: One page of ASCII characters See ASCII chart. requires approximately 2KB of storage; therefore, 1GB stores approximately 500,000 ASCII ASCII or American Standard Code for Information Interchange, a set of codes used to represent letters, numbers, a few symbols, and control characters. Originally designed for teletype operations, it has found wide application in computers. pages. A black and white document scanned at 200 dots per inch (dpi) and compressed 10:1 requires approximately 50KB of storage; therefore, 1GB stores approximately 20,000 page-size documents. Without compression, 1GB stores only approximately 2,000 scanned pages. A full-color page scanned at 200 dots per inch (dpi) requires approximately 12MB of storage; therefore, 1GB stores as few as 83 full-color, page-size documents (depending upon the color mode See bit depth and color space. ). Resolution has a major effect on the number of bytes generated when scanning documents or images. If the resolution of a document or image is doubled from 200 dpi to 400 dpi, the number of bytes per document is quadrupled. To accommodate the growth of file size, many technologically innovative companies began developing new technologies that would deliver great leaps in storage capacity, performance, and reliability. For example, in 1995, the 100MB Zip disk A 3.5" removable disk drive from Iomega. Zip disks come in 100MB, 250MB and 750MB varieties, with the latter introduced in 2002 using USB and FireWire interfaces. The 250MB drives, introduced in 1998, also read and write 100MB disks. was introduced. In that same year, another high-capacity, midrange midrange Epidemiology The halfway point or midpoint in a set of observations; for most data, MR is calculated as the sum of the smallest observation and the largest observation, divided by 2; for age data, one is added to the numerator; a midrange is usually storage format made its debut-DLTtape IV. When drive manufacturers Quantum and Fujifilm first worked together to introduce DLTtape IV media, it offered the then-unrivaled capacity of 20GB (40GB/compressed) operating on the DLT (Digital Linear Tape) A magnetic tape technology originally developed by Digital for its VAX line. The technology was later sold to Quantum, which makes it available to other manufacturers. DLT uses half-inch, single-hub cartridges similar to IBM's 3480/3490/3590 line. 4000 drive. With the DLT 8000 drive, DLTtape IV offered a native sustained data transfer rate of 6MB/second and a capacity of 40GB (80GB/compressed). It was the ideal solution for mid- to large-size businesses that were seeking to meet the higher-capacity, faster transfer rates, and increased reliability required by midrange systems, network servers, and high-end workstations. As DLTtape technology has evolved over time, it has maintained backward read and write compatibility with the full line of DLTtape drives. At the same time, the promise of future compatibility and upgradeability has helped to make DLTtape IV tape cartridges See cartridge. today's most widely used data storage medium of its kind. The New Next-Generation Formats: ITO Ito, city (1990 pop. 71,223), Shizuoka prefecture, central Honshu, Japan, on the Izu Peninsula and the Sagami Sea. It is an important fishing port and hot spring resort. See indium. And Super DLTtape This summer, the Linear Tape-Open (LTO (Linear Tape Open) A family of open magnetic tape standards developed by HP, IBM and Quantum (formerly the Certance subsidiary of Seagate) that are licensed to third-party vendors. LTO cartridges contain a memory that stores historical usage data. ) consortium of Hewlett-Packard, IBM (International Business Machines Corporation, Armonk, NY, www.ibm.com) The world's largest computer company. IBM's product lines include the S/390 mainframes (zSeries), AS/400 midrange business systems (iSeries), RS/6000 workstations and servers (pSeries), Intel-based servers (xSeries) , and Seagate reported that Fujifilm was one of only two media manufacturers that had successfully completed the verification testing process for manufacturing Ultrium 1 100GB tape cartridges. In August, Fujifilm announced it would begin branding its own Ultrium 1 data cartridges (1) A cartridge used to hold computer data. See cartridge. (2) (Data Cartridge) A 5.25" QIC-style magnetic tape technology that originally used the DC-6000 model designation. Tandberg Data (www.tandberg. and shipping Ultrium 1 product to IBM and other drive makers as well as to private label media manufacturers. LTO Ultrium takes both capacity and speed to the next level. It offers a first-generation native capacity of 100GB (200GB/compressed) and a native transfer rate of 1020MB/sec. A fourth-generation migration path will bring a compressed capacity of 1 .6TB with an unrivaled data transfer rate of 320MB/Sec. Joining DLTtape IV in the mid-range and enterprise stQrage market place, the LTO Ultrium format offers businesses a new alternative for reliable, high-quality tape backup Using magnetic tape for storing duplicate copies of hard disk files. Users can add an internal or external tape drive to their desktop computers for backup purposes, and files are typically copied to the tapes using a backup utility that updates on a periodic schedule. solutions. Hoping to leverage the enormous existing installed base of DLTtape technology, Quantum is introducing its Super DLTtape drives to today's storage community. With these drives, first generation Super DLTtape media will provide a native 110GB (220GB/compressed) of storage capacity and will be fully backward-read compatible with DLTtape IV cartridge systems. The table compares DLTtape IV and the two new next-generation storage formats. Media manufacturers must maintain a storage format-neutral philosophy. This philosophy has involved working intimately with a wide range of drive manufacturers to develop media for their drives. Our mutual goal has been-and continues to be-to provide both consumers and business customers with a choice of highquality storage options to meet their exact needs and requirements. Innovati on n, quality, and choice-that has been the trend driving the storage media market during the past decade, and we fully expect that that trend will continue for the next decade. Steven A. Solomon is the senior vice president and general manager in the computer products division at Fuji Photo Film U.S.A., Inc. (Elimsford, NY).
FORMAT NATIVE NATIVE DATA GENERAL
CAPACITY TRANSFER AVAILABILITY
RATE
DLTtape IV 40GB 6MB/sec Since 1995
LTO Ultrium 1 100GB 10-20MB/sec Since Fall 2000
Super DLTtape 1 110GB 10-20MB/sec Coming Soon
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