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Thinking about writing your memoirs
Thinking about writing your memoirs – putting your life story down on paper for all eternity? Why not skip the repetitive strain injury and just capture your whole life on full-video, putting it all in a device the size of a sugar cube? It might not be as far off as you think.
Currie Munce, director of IBM’s Advanced HDD Technology Storage System Division, has one avowed goal: Build bigger storage. Recently Munce and his fellow Ph.Ds restored Big Blue’s lead in the disk space race with a new world record for areal (bit) density: 35.3 gigabits per square inch – roughly three times as dense as any drive shipping at press time.
During the 1990s, areal density doubled every 18 months, keeping pace with the transistor density gains predicted by Moore’s Law. But increasingly daunting technical challenges face those who would push the storage envelope further. “I think magnetic recording technology has another good 5 to 10 years” says Munce. “After that, we’ll see substantial difficulties with further advances at the pace people are accustomed to.”
From here on, a phenomenon called superparamagnetism threatens to make densely-packed bits unstable. Provided that new developments continue to thwart superparamagnetic corruption, scientists speculate that the theoretical limit for discrete bit recording is 10 terabits per square inch (1 terabit = 10 gigabit).
Approaching this limit will require new technologies. Two possible contenders are atomic force microscopy (AFM) and holographic storage.
AFM would use a spinning plastic disk, perhaps inside a wristwatch, and a tiny, 10-micron cantilever with a 40-angstrom tip (an angstrom represents the approximate radius of an atom) to write data. In theory, AFM will allow densities of 300 to 400 gigabits per square inch.
While AFM is still in the lab, holographic storage is closer to reality. According to Rusty Rosenberger, optical program manager for Imation, “We are targeting a 40MB-per-second transfer rate.” Future iterations of holographic systems should improve substantially.
The three-dimensional nature of holography makes it an appealing storage medium because “page” of data can be superimposed on a single volume – imagine transferring a whole page of text at once as opposed to reading each letter in sequence. Hans Coufal, manager of IBM’s New Directions in Science and Technology Research division, predicts that the fast access rates and transfer times of holographic storage will lead to improved network searches, video on demand, high-end servers, enterprise computing, and supercomputing.
Meanwhile, also-run technologies are thriving. Tape, first used for data storage in 1951 with the Univac I, has been revitalized by the corporate hunger for affordable archiving solutions. In the consumer arena, says Dataquest analyst Mary Craig, recordable CD-ROMs and DVDs will remain the dominant high-capacity removable storage media for the next decade. Despite their failure to match the areal density gains of hard disks, optical disks are cheap to produce, making them ideal for software distribution (until a mature digital rights management system facilitates online delivery). Finally, solid state options such as flash cards can’t yet match the pricing of hard disks at high capacities.
Further out, scientists salivate over the prospect of data manipulation and storage on an atomic level. Because consumer demand for capacity is lagging behind what technology can deliver, bringing new storage options to the masses will depend on seeing the need for more space.
Currie Munce, director of IBM’s Advanced HDD Technology Storage System Division, has one avowed goal: Build bigger storage. Recently Munce and his fellow Ph.Ds restored Big Blue’s lead in the disk space race with a new world record for areal (bit) density: 35.3 gigabits per square inch – roughly three times as dense as any drive shipping at press time.
During the 1990s, areal density doubled every 18 months, keeping pace with the transistor density gains predicted by Moore’s Law. But increasingly daunting technical challenges face those who would push the storage envelope further. “I think magnetic recording technology has another good 5 to 10 years” says Munce. “After that, we’ll see substantial difficulties with further advances at the pace people are accustomed to.”
From here on, a phenomenon called superparamagnetism threatens to make densely-packed bits unstable. Provided that new developments continue to thwart superparamagnetic corruption, scientists speculate that the theoretical limit for discrete bit recording is 10 terabits per square inch (1 terabit = 10 gigabit).
Approaching this limit will require new technologies. Two possible contenders are atomic force microscopy (AFM) and holographic storage.
AFM would use a spinning plastic disk, perhaps inside a wristwatch, and a tiny, 10-micron cantilever with a 40-angstrom tip (an angstrom represents the approximate radius of an atom) to write data. In theory, AFM will allow densities of 300 to 400 gigabits per square inch.
While AFM is still in the lab, holographic storage is closer to reality. According to Rusty Rosenberger, optical program manager for Imation, “We are targeting a 40MB-per-second transfer rate.” Future iterations of holographic systems should improve substantially.
The three-dimensional nature of holography makes it an appealing storage medium because “page” of data can be superimposed on a single volume – imagine transferring a whole page of text at once as opposed to reading each letter in sequence. Hans Coufal, manager of IBM’s New Directions in Science and Technology Research division, predicts that the fast access rates and transfer times of holographic storage will lead to improved network searches, video on demand, high-end servers, enterprise computing, and supercomputing.
Meanwhile, also-run technologies are thriving. Tape, first used for data storage in 1951 with the Univac I, has been revitalized by the corporate hunger for affordable archiving solutions. In the consumer arena, says Dataquest analyst Mary Craig, recordable CD-ROMs and DVDs will remain the dominant high-capacity removable storage media for the next decade. Despite their failure to match the areal density gains of hard disks, optical disks are cheap to produce, making them ideal for software distribution (until a mature digital rights management system facilitates online delivery). Finally, solid state options such as flash cards can’t yet match the pricing of hard disks at high capacities.
Further out, scientists salivate over the prospect of data manipulation and storage on an atomic level. Because consumer demand for capacity is lagging behind what technology can deliver, bringing new storage options to the masses will depend on seeing the need for more space.
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Thinking about writing your memoirs – putting your life story down on paper for all eternity? Why not skip the repetitive strain injury and just capture your whole life on full-video, putting it all in a device the size of a sugar cube? It might not be as far off as you think.
Currie Munce, director of IBM’s Advanced HDD Technology Storage System Division, has one avowed goal: Build bigger storage. Recently Munce and his fellow Ph.Ds restored Big Blue’s lead in the disk space race with a new world record for areal (bit) density: 35.3 gigabits per square inch – roughly three times as dense as any drive shipping at press time.
During the 1990s, areal density doubled every 18 months, keeping pace with the transistor density gains predicted by Moore’s Law. But increasingly daunting technical challenges face those who would push the storage envelope further. “I think magnetic recording technology has another good 5 to 10 years” says Munce. “After that, we’ll see substantial difficulties with further advances at the pace people are accustomed to.”
From here on, a phenomenon called superparamagnetism threatens to make densely-packed bits unstable. Provided that new developments continue to thwart superparamagnetic corruption, scientists speculate that the theoretical limit for discrete bit recording is 10 terabits per square inch (1 terabit = 10 gigabit).
Approaching this limit will require new technologies. Two possible contenders are atomic force microscopy (AFM) and holographic storage.
AFM would use a spinning plastic disk, perhaps inside a wristwatch, and a tiny, 10-micron cantilever with a 40-angstrom tip (an angstrom represents the approximate radius of an atom) to write data. In theory, AFM will allow densities of 300 to 400 gigabits per square inch.
While AFM is still in the lab, holographic storage is closer to reality. According to Rusty Rosenberger, optical program manager for Imation, “We are targeting a 40MB-per-second transfer rate.” Future iterations of holographic systems should improve substantially.
The three-dimensional nature of holography makes it an appealing storage medium because “page” of data can be superimposed on a single volume – imagine transferring a whole page of text at once as opposed to reading each letter in sequence. Hans Coufal, manager of IBM’s New Directions in Science and Technology Research division, predicts that the fast access rates and transfer times of holographic storage will lead to improved network searches, video on demand, high-end servers, enterprise computing, and supercomputing.
Meanwhile, also-run technologies are thriving. Tape, first used for data storage in 1951 with the Univac I, has been revitalized by the corporate hunger for affordable archiving solutions. In the consumer arena, says Dataquest analyst Mary Craig, recordable CD-ROMs and DVDs will remain the dominant high-capacity removable storage media for the next decade. Despite their failure to match the areal density gains of hard disks, optical disks are cheap to produce, making them ideal for software distribution (until a mature digital rights management system facilitates online delivery). Finally, solid state options such as flash cards can’t yet match the pricing of hard disks at high capacities.
Further out, scientists salivate over the prospect of data manipulation and storage on an atomic level. Because consumer demand for capacity is lagging behind what technology can deliver, bringing new storage options to the masses will depend on seeing the need for more space.
Currie Munce, director of IBM’s Advanced HDD Technology Storage System Division, has one avowed goal: Build bigger storage. Recently Munce and his fellow Ph.Ds restored Big Blue’s lead in the disk space race with a new world record for areal (bit) density: 35.3 gigabits per square inch – roughly three times as dense as any drive shipping at press time.
During the 1990s, areal density doubled every 18 months, keeping pace with the transistor density gains predicted by Moore’s Law. But increasingly daunting technical challenges face those who would push the storage envelope further. “I think magnetic recording technology has another good 5 to 10 years” says Munce. “After that, we’ll see substantial difficulties with further advances at the pace people are accustomed to.”
From here on, a phenomenon called superparamagnetism threatens to make densely-packed bits unstable. Provided that new developments continue to thwart superparamagnetic corruption, scientists speculate that the theoretical limit for discrete bit recording is 10 terabits per square inch (1 terabit = 10 gigabit).
Approaching this limit will require new technologies. Two possible contenders are atomic force microscopy (AFM) and holographic storage.
AFM would use a spinning plastic disk, perhaps inside a wristwatch, and a tiny, 10-micron cantilever with a 40-angstrom tip (an angstrom represents the approximate radius of an atom) to write data. In theory, AFM will allow densities of 300 to 400 gigabits per square inch.
While AFM is still in the lab, holographic storage is closer to reality. According to Rusty Rosenberger, optical program manager for Imation, “We are targeting a 40MB-per-second transfer rate.” Future iterations of holographic systems should improve substantially.
The three-dimensional nature of holography makes it an appealing storage medium because “page” of data can be superimposed on a single volume – imagine transferring a whole page of text at once as opposed to reading each letter in sequence. Hans Coufal, manager of IBM’s New Directions in Science and Technology Research division, predicts that the fast access rates and transfer times of holographic storage will lead to improved network searches, video on demand, high-end servers, enterprise computing, and supercomputing.
Meanwhile, also-run technologies are thriving. Tape, first used for data storage in 1951 with the Univac I, has been revitalized by the corporate hunger for affordable archiving solutions. In the consumer arena, says Dataquest analyst Mary Craig, recordable CD-ROMs and DVDs will remain the dominant high-capacity removable storage media for the next decade. Despite their failure to match the areal density gains of hard disks, optical disks are cheap to produce, making them ideal for software distribution (until a mature digital rights management system facilitates online delivery). Finally, solid state options such as flash cards can’t yet match the pricing of hard disks at high capacities.
Further out, scientists salivate over the prospect of data manipulation and storage on an atomic level. Because consumer demand for capacity is lagging behind what technology can deliver, bringing new storage options to the masses will depend on seeing the need for more space.
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Suy nghĩ về việc viết hồi ký của mình - đưa câu chuyện cuộc sống của bạn ra giấy cho tất cả vĩnh cửu? Tại sao không bỏ qua những chấn thương căng thẳng lặp đi lặp lại và chỉ cần nắm bắt toàn bộ cuộc sống của bạn trên toàn video, đặt nó tất cả trong một thiết bị kích thước của một viên đường? Nó có thể không được như xa như bạn nghĩ. Currie Munce, giám đốc của Advanced HDD Storage Technology Bộ phận Hệ thống của IBM, có một mục tiêu thú nhận: Xây dựng lưu trữ lớn hơn. Gần đây Munce và tiến sĩ đồng nghiệp của ông lại dẫn Big Blue trong cuộc chạy đua không gian đĩa với một kỷ lục thế giới mới cho areal (bit) Mật độ: 35,3 gigabit mỗi inch vuông - gấp ba lần như dày đặc như bất kỳ ổ đĩa vận chuyển tại thời điểm báo chí. Trong năm 1990, mật độ dày gấp đôi mỗi 18 tháng, bắt kịp với tăng mật độ bóng bán dẫn dự đoán của định luật Moore. Nhưng những thách thức kỹ thuật ngày càng khó khăn phải đối mặt với những người sẽ thúc đẩy các phong bì chứa hơn nữa. "Tôi nghĩ rằng công nghệ ghi từ tính có khác tốt 5-10 năm" Munce nói. "Sau đó, chúng ta sẽ thấy những khó khăn đáng kể với tiến bộ hơn nữa vào những người đã quen với nhịp độ." Kể từ đây, một hiện tượng được gọi là Siêu thuận từ đe dọa để làm bit đông đóng gói không ổn định. Với điều kiện phát triển mới tiếp tục ngăn chặn tham nhũng siêu thuận từ, các nhà khoa học suy đoán rằng các giới hạn lý thuyết để ghi âm bit rời rạc là 10 terabit mỗi inch vuông (1 terabit = 10 gigabit). Tiếp cận giới hạn này sẽ đòi hỏi công nghệ mới. Hai ứng cử viên có thể là nguyên tử lực kính hiển vi (AFM) và lưu trữ holographic. AFM sẽ sử dụng một đĩa quay bằng nhựa, có lẽ bên trong đồng hồ đeo tay, và một nhỏ, 10-micron cantilever với một tip 40 angstrom (một Angstrom đại diện bán kính gần đúng của một nguyên tử) để ghi dữ liệu. Về lý thuyết, AFM sẽ cho phép mật độ của 300-400 gigabits mỗi inch vuông. Trong khi AFM vẫn còn trong phòng thí nghiệm, lưu trữ holographic là gần gũi hơn với thực tế. Theo Rusty Rosenberger, quản lý chương trình quang cho Imation, "Chúng tôi đang nhắm mục tiêu một tỷ lệ 40MB mỗi giây chuyển giao." Lặp đi lặp lại trong tương lai của hệ thống ba chiều nên cải thiện đáng kể. Tính chất ba chiều của hologram làm cho nó trở thành một phương tiện lưu trữ hấp dẫn vì "trang "dữ liệu có thể được đặt lên trên một khối duy nhất - tưởng tượng chuyển giao toàn bộ trang văn bản cùng một lúc như trái ngược với đọc từng chữ cái theo thứ tự. Hans Coufal, quản lý của IBM hướng mới trong bộ phận Nghiên cứu Khoa học và Công nghệ, dự đoán rằng tốc độ truy cập nhanh chóng và thời gian chuyển nhượng lưu trữ holographic sẽ dẫn đến cải thiện tìm kiếm mạng, video trên các máy chủ yêu cầu, cao cấp, điện toán doanh nghiệp, và các siêu máy tính. Trong khi đó , công nghệ này cũng chạy rất phát đạt. Tape, đầu tiên được sử dụng để lưu trữ dữ liệu vào năm 1951 với Univac I, đã được hồi sinh bởi sự đói khát của công ty cho các giải pháp lưu trữ giá cả phải chăng. Trong lĩnh vực tiêu dùng, theo nhà phân tích Dataquest Mary Craig, ghi CD-ROM và DVD sẽ vẫn là dung lượng cao phương tiện lưu trữ di động chiếm ưu thế trong thập kỷ tiếp theo. Mặc dù thất bại của họ để phù hợp với mức tăng mật độ dày đặc của các ổ đĩa cứng, đĩa quang rẻ để sản xuất, làm cho chúng lý tưởng cho việc phân phối phần mềm (cho đến khi một hệ thống quản lý bản quyền kỹ thuật số trưởng thành tạo điều kiện giao hàng trực tuyến). Cuối cùng, lựa chọn trạng thái rắn như thẻ flash có thể chưa phù hợp với giá cả của các ổ đĩa cứng ở năng lực cao. Hơn nữa ra, các nhà khoa học tiết nước bọt trên các khách hàng tiềm năng của các thao tác dữ liệu và lưu trữ trên một cấp độ nguyên tử. Bởi vì nhu cầu của người tiêu dùng đối với công suất là tụt hậu đằng sau những gì công nghệ có thể cung cấp, mang lại lựa chọn lưu trữ mới cho quần chúng sẽ phụ thuộc vào nhìn thấy sự cần thiết cho không gian hơn.
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