This document discusses optical storage devices such as CDs and DVDs. It covers the history and development of these technologies from early analog laserdiscs to modern writable optical disks. The key types of optical disks are described as read-only, write-once, and rewritable. Details are provided on technologies such as ablative recording and phase-change media that enable write-once and rewritable functionality.
This document provides an overview of 3D optical data storage technology. It discusses how 3D optical storage uses lasers to record and read data in multiple layers within a storage medium, unlike 2D formats like CDs that only use single layers. The document outlines the key components of 3D optical storage systems including lasers, lenses, photosensitive materials, and discusses advantages like high storage capacity and durability and disadvantages such as limited reusability. It concludes that 3D optical storage could provide a new way to arrange high-density, three-dimensional optical memory devices.
3D OPTICAL STORAGE TECHNOLOGY technical seminar 4B.pptxMallaAbhinaya
This document discusses optical storage and 3D optical data storage. It describes how optical storage works by using lasers to burn data into optical disks in a spiral track. 3D optical storage can store data in three dimensions rather than two, potentially storing much more data in the same physical space. Some challenges to commercializing 3D optical storage have been destructive reading processes and issues with media stability and sensitivity. The document outlines the basic components, processes, and form factors of 3D optical storage systems.
The document discusses various storage technologies used in computing. It describes the two primary storage types as magnetic and optical. Magnetic storage includes hard disks, diskettes, magnetic tape, and solid-state drives. Optical storage includes CDs, DVDs, and Blu-ray discs. Other technologies discussed include smart cards, USB flash drives, and RFID tags.
This document discusses computer memory and storage. It defines primary and secondary memory, and describes their key differences. Primary memory, also called main memory, is volatile and used for processing. It has high access speeds but limited capacity. Secondary memory is non-volatile and used for long-term storage of large volumes of data. Common types of primary memory include RAM, ROM, and cache. Common forms of secondary memory include hard disks, optical disks, magnetic tapes, USB drives, and cloud storage. The document evaluates various storage media and provides details on their characteristics like capacity, access times, and usage.
The document discusses the history and technology of optical storage. It describes three generations:
First generation used infrared lasers, storing up to 700MB on CDs. Second generation used visible red lasers, allowing DVDs to store up to 4.7GB. Third generation uses blue-violet lasers and greater precision, enabling discs like Blu-ray to store over 5TB of data.
The document discusses computer memory and its types. It explains that memory is required to store data and instructions before, during, and after processing by the CPU. There are two main types of memory: primary and secondary. Primary memory (RAM and ROM) is high-speed volatile memory that is used for temporary storage and processing. Secondary memory (hard disks, optical disks, magnetic tapes, etc.) is non-volatile storage for long-term storage and retrieval of data. The document provides details about different types of primary and secondary storage, their characteristics, uses, and examples.
Harshitha H C presented a technical seminar on 3D optical data storage. The presentation covered an introduction to 3D optical data storage technology, how it works by focusing lasers within storage media to write and read data in three dimensions. It discussed media design and manufacturing, commercial development efforts, basic components like lasers and photosensitive materials, advantages like durability and applications in satellite data storage. The conclusion was that 3D optical storage is well-suited for future data storage needs by providing high-capacity, archivable storage.
This document provides an overview of 3D optical data storage technology. It discusses how 3D optical storage uses lasers to record and read data in multiple layers within a storage medium, unlike 2D formats like CDs that only use single layers. The document outlines the key components of 3D optical storage systems including lasers, lenses, photosensitive materials, and discusses advantages like high storage capacity and durability and disadvantages such as limited reusability. It concludes that 3D optical storage could provide a new way to arrange high-density, three-dimensional optical memory devices.
3D OPTICAL STORAGE TECHNOLOGY technical seminar 4B.pptxMallaAbhinaya
This document discusses optical storage and 3D optical data storage. It describes how optical storage works by using lasers to burn data into optical disks in a spiral track. 3D optical storage can store data in three dimensions rather than two, potentially storing much more data in the same physical space. Some challenges to commercializing 3D optical storage have been destructive reading processes and issues with media stability and sensitivity. The document outlines the basic components, processes, and form factors of 3D optical storage systems.
The document discusses various storage technologies used in computing. It describes the two primary storage types as magnetic and optical. Magnetic storage includes hard disks, diskettes, magnetic tape, and solid-state drives. Optical storage includes CDs, DVDs, and Blu-ray discs. Other technologies discussed include smart cards, USB flash drives, and RFID tags.
This document discusses computer memory and storage. It defines primary and secondary memory, and describes their key differences. Primary memory, also called main memory, is volatile and used for processing. It has high access speeds but limited capacity. Secondary memory is non-volatile and used for long-term storage of large volumes of data. Common types of primary memory include RAM, ROM, and cache. Common forms of secondary memory include hard disks, optical disks, magnetic tapes, USB drives, and cloud storage. The document evaluates various storage media and provides details on their characteristics like capacity, access times, and usage.
The document discusses the history and technology of optical storage. It describes three generations:
First generation used infrared lasers, storing up to 700MB on CDs. Second generation used visible red lasers, allowing DVDs to store up to 4.7GB. Third generation uses blue-violet lasers and greater precision, enabling discs like Blu-ray to store over 5TB of data.
The document discusses computer memory and its types. It explains that memory is required to store data and instructions before, during, and after processing by the CPU. There are two main types of memory: primary and secondary. Primary memory (RAM and ROM) is high-speed volatile memory that is used for temporary storage and processing. Secondary memory (hard disks, optical disks, magnetic tapes, etc.) is non-volatile storage for long-term storage and retrieval of data. The document provides details about different types of primary and secondary storage, their characteristics, uses, and examples.
Harshitha H C presented a technical seminar on 3D optical data storage. The presentation covered an introduction to 3D optical data storage technology, how it works by focusing lasers within storage media to write and read data in three dimensions. It discussed media design and manufacturing, commercial development efforts, basic components like lasers and photosensitive materials, advantages like durability and applications in satellite data storage. The conclusion was that 3D optical storage is well-suited for future data storage needs by providing high-capacity, archivable storage.
The document discusses different types of computer memory. Primary memory, also called main memory, is used by the CPU and stores data and instructions during processing. It is volatile and comes in RAM and ROM varieties. Secondary memory is non-volatile storage like hard disks, which are larger but slower than primary memory. Optical disks like CDs, DVDs, and Blu-rays are also discussed as secondary storage mediums.
Secondary storage devices include external storage mediums like USB drives, external hard disks, and zip drives that are used to backup and store files externally from the main computer. Peripheral devices expand the capabilities of the host computer but are not part of the core architecture, and include input, output, and storage devices. The control unit decodes instructions and controls data flow and timing in the central processing unit. It regulates communication between the CPU and peripheral devices. The arithmetic logic unit performs arithmetic and logical operations and works with the control unit to execute instructions.
A Short Introduction About the Holographic Data Storage System. Its a future Technology for store large amount of Data Using Holographic Data Storage System.
This document summarizes key aspects of hard disk drive technology. It discusses how disk drives have evolved from early magnetic drums and tapes to become standard components in modern computers. It describes how Winchester disk drives use sealed enclosures and aerodynamic sliders to allow heads to fly just micro-inches above disks. The document outlines trends in disk drive capacity, form factor, and recording density. These trends involve innovations like magnetoresistive heads and PRML channels that allow for higher areal densities and capacities by improving read/write functions. The goal is to achieve 1 gigabit per square inch areal density by 2000 through advances in media, heads, and other technologies.
This document discusses holographic data storage technology (HDST). It provides a brief history of data storage medias, describes how holograms work, and explains the recording and reading processes in HDST. Key advantages of HDST include significantly higher storage density compared to optical discs, high durability, and fast read/write speeds of 1 Gbps. Challenges include the complexity of aligning system components and the need for high-quality recording materials. Potential applications include exascale computing and data mining.
Magnetic tape is a storage medium on a reel or cartridge with a magnetic coating that allows data to be written, erased, and rewritten. However, magnetic tapes provide only sequential access to data, requiring the tape to rewind or fast forward to requested data, making them unsuitable for frequently updated files. Optical disks like CDs and DVDs store large amounts of data using laser-readable spots on spiral tracks, allowing for higher storage densities than tapes or floppy disks. Recordable optical disks like CD-Rs and DVD-Rs allow users to permanently write data to the disk, while CD-RWs and DVD-RWs allow rewriting data. Cache memory provides faster access to frequently used instructions and data by
Storage devices are a evolving nowadays, especially because our storage appetites are growing every second. The presentation talks about various types of storage, why it is used, and basically, the advantages and disadvantages of the storage discussed.
The document discusses the hierarchy of computer systems from supercomputers to microcomputers. It explains that supercomputers are the most powerful for processing large datasets. Mainframes are less powerful than supercomputers and are used for applications like banking. Midrange computers include minicomputers and servers. Microcomputers range from desktop PCs to mobile devices. The CPU and computer memory are also described.
This document discusses different types of secondary storage devices and their characteristics. It begins by explaining the limitations of primary storage and need for secondary storage. It then classifies commonly used secondary storage devices as sequential-access devices like magnetic tapes and random-access devices like magnetic disks. Specific device details covered include half-inch tape reels, tape cartridges, floppy disks, hard disks, CDs, DVDs, flash drives and memory cards. The document concludes by presenting the storage hierarchy from fastest and most expensive to slowest and least expensive storage.
The document discusses various methods for storing and retrieving images, including tape drives, hard disks, optical discs like CDs and DVDs, and removable media like zip disks. It describes the basic technology behind each storage type, their capacities and transfer speeds, common formats, and advantages and limitations. Tape drives provide large storage capacities but slow sequential access, while hard disks and optical discs offer faster random access but have more limited capacities. Removable disks like zip disks also provide portable storage.
Hard disk & Optical disk (college group project)Vshal_Rai
- Hard disk drives (HDDs) are devices used for digital data storage. They consist of rapidly rotating discs coated with magnetic material. Magnetic heads write data to and read data from the disc surfaces.
- HDDs were first introduced in 1956 and have since decreased dramatically in size and cost, becoming standard in personal computers by the late 1980s. Capacities have also increased greatly, with modern HDDs capable of storing terabytes of data.
- Optical discs like CDs and DVDs store data in the form of pits and lands on a reflective surface. They were invented in the late 1950s and early 1960s and are now commonly used to store music, video, and computer programs and data.
These Notes from the class of BS EDUCATION 1st Semester (Spring) Session 2023-2027 Teacher :Ch Naveed Afzal
semester started in march 2023 and end in july 2023
The document discusses various data storage devices. It describes floppy disks, CDs, DVDs, hard disks, USB flash drives, and different types of ROM and RAM. Floppy disks can store up to 1.4 MB of data but newer ones can store up to 250MB. CDs standardly hold up to 80 minutes of audio or 700MB of data. DVDs have significantly higher storage capacity than CDs, able to hold up to 17GB. Hard disks use spinning magnetic disks to store data and have faster access times than removable media. USB flash drives have flash memory and are small, portable, and write/rewrite data. The different types of ROM and RAM each have their own characteristics for
Secondary storage devices store information even when a computer is powered off. Common secondary storage devices include floppy disks, hard disks, magnetic tapes, flash drives, and optical disks. Magnetic tapes and disks are sequential access devices that read/write data in sequence, while hard disks and optical disks are direct access devices that allow random access to data. Secondary storage provides large storage capacity at lower costs than primary storage and is used to store programs and data.
Secondary storage devices such as hard disks, CDs, USB drives, and Blu-ray discs are used for bulk storage of data with large capacities and transfer data to main memory for processing. Hard disks provide fast storage and high capacities, storing data on magnetic disks accessed by read/write heads. CDs and Blu-ray discs use optical technology to store digital data in pits encoded in spiral tracks, with Blu-ray using a blue laser to achieve higher densities. USB drives are portable flash memory devices that can easily transfer data between computers. Secondary storage is cheaper than main memory and has slower access times.
Floppy disks, CDs, DVDs, tape drives, flash memory, and memory cards are described as common data storage devices. Floppy disks were widely used in the late 20th century but have been largely replaced by methods with greater storage capacities like USB flash drives, external hard drives, and cloud storage. CDs and DVDs introduced rewritable formats like CD-RW and DVD-RW that allowed erasing and rewriting data multiple times compared to write-once formats. Tape drives provide sequential access storage for offline archival, while solid state flash memories like memory cards have faster random access.
This document provides an overview of various data storage technologies and devices used in client-server systems, including magnetic disks, tapes, CD-ROMs, WORM disks, optical disks, RAID configurations, network protection devices, power protection devices, and remote system management. It describes the basic workings and purposes of these different components that are crucial for reliable data storage and system uptime in client-server computing environments.
COMPACT PRESERVATION OF SCRAMBLED CD-ROM DATAijcsit
When preserving CD-ROM discs, data sectors are often read in a so-called “scrambled mode” in order to preserve as much data as possible. This scrambled data is later unscrambled and further processed into a standard CD-ROM disc image. The process of converting the scrambled data into a standard CD-ROM disc image is potentially lossy, but standard CD-ROM disc images exhibit much higher software compatibility and have greater usability compared to the scrambled data from which they are derived. Consequently, for preservation purposes, it is often necessary to store both the scrambled data and the corresponding standard disc image, resulting in greatly increased storage demands compared to storing just one or the other. Here, a method that enables compact storage of scrambled data alongside the corresponding (unscrambled) standard CD-ROM disc image is introduced. The method produces a compact representation of the scrambled data that is derived from the unscrambled disc image. The method allows for (1) storage of the standard unscrambled disc image in unmodified form, (2) easy reconstruction of the scrambled data as needed, and (3) a substantial space savings (in the typical case) compared to storing the scrambled data using standard data compression techniques.
This document provides an overview of computer storage fundamentals, including primary and secondary storage. It discusses the characteristics and uses of different types of primary storage (RAM and ROM) and secondary storage devices (floppy disks, hard disks, optical disks, USB flash drives, and magnetic tapes). RAM is temporary and volatile, holding data currently being processed, while ROM is permanent and non-volatile. Secondary storage devices are used to permanently store large amounts of non-essential data and include magnetic and optical media with varying speeds and capacities.
A Strategic Approach: GenAI in EducationPeter Windle
Artificial Intelligence (AI) technologies such as Generative AI, Image Generators and Large Language Models have had a dramatic impact on teaching, learning and assessment over the past 18 months. The most immediate threat AI posed was to Academic Integrity with Higher Education Institutes (HEIs) focusing their efforts on combating the use of GenAI in assessment. Guidelines were developed for staff and students, policies put in place too. Innovative educators have forged paths in the use of Generative AI for teaching, learning and assessments leading to pockets of transformation springing up across HEIs, often with little or no top-down guidance, support or direction.
This Gasta posits a strategic approach to integrating AI into HEIs to prepare staff, students and the curriculum for an evolving world and workplace. We will highlight the advantages of working with these technologies beyond the realm of teaching, learning and assessment by considering prompt engineering skills, industry impact, curriculum changes, and the need for staff upskilling. In contrast, not engaging strategically with Generative AI poses risks, including falling behind peers, missed opportunities and failing to ensure our graduates remain employable. The rapid evolution of AI technologies necessitates a proactive and strategic approach if we are to remain relevant.
Assessment and Planning in Educational technology.pptxKavitha Krishnan
In an education system, it is understood that assessment is only for the students, but on the other hand, the Assessment of teachers is also an important aspect of the education system that ensures teachers are providing high-quality instruction to students. The assessment process can be used to provide feedback and support for professional development, to inform decisions about teacher retention or promotion, or to evaluate teacher effectiveness for accountability purposes.
The document discusses different types of computer memory. Primary memory, also called main memory, is used by the CPU and stores data and instructions during processing. It is volatile and comes in RAM and ROM varieties. Secondary memory is non-volatile storage like hard disks, which are larger but slower than primary memory. Optical disks like CDs, DVDs, and Blu-rays are also discussed as secondary storage mediums.
Secondary storage devices include external storage mediums like USB drives, external hard disks, and zip drives that are used to backup and store files externally from the main computer. Peripheral devices expand the capabilities of the host computer but are not part of the core architecture, and include input, output, and storage devices. The control unit decodes instructions and controls data flow and timing in the central processing unit. It regulates communication between the CPU and peripheral devices. The arithmetic logic unit performs arithmetic and logical operations and works with the control unit to execute instructions.
A Short Introduction About the Holographic Data Storage System. Its a future Technology for store large amount of Data Using Holographic Data Storage System.
This document summarizes key aspects of hard disk drive technology. It discusses how disk drives have evolved from early magnetic drums and tapes to become standard components in modern computers. It describes how Winchester disk drives use sealed enclosures and aerodynamic sliders to allow heads to fly just micro-inches above disks. The document outlines trends in disk drive capacity, form factor, and recording density. These trends involve innovations like magnetoresistive heads and PRML channels that allow for higher areal densities and capacities by improving read/write functions. The goal is to achieve 1 gigabit per square inch areal density by 2000 through advances in media, heads, and other technologies.
This document discusses holographic data storage technology (HDST). It provides a brief history of data storage medias, describes how holograms work, and explains the recording and reading processes in HDST. Key advantages of HDST include significantly higher storage density compared to optical discs, high durability, and fast read/write speeds of 1 Gbps. Challenges include the complexity of aligning system components and the need for high-quality recording materials. Potential applications include exascale computing and data mining.
Magnetic tape is a storage medium on a reel or cartridge with a magnetic coating that allows data to be written, erased, and rewritten. However, magnetic tapes provide only sequential access to data, requiring the tape to rewind or fast forward to requested data, making them unsuitable for frequently updated files. Optical disks like CDs and DVDs store large amounts of data using laser-readable spots on spiral tracks, allowing for higher storage densities than tapes or floppy disks. Recordable optical disks like CD-Rs and DVD-Rs allow users to permanently write data to the disk, while CD-RWs and DVD-RWs allow rewriting data. Cache memory provides faster access to frequently used instructions and data by
Storage devices are a evolving nowadays, especially because our storage appetites are growing every second. The presentation talks about various types of storage, why it is used, and basically, the advantages and disadvantages of the storage discussed.
The document discusses the hierarchy of computer systems from supercomputers to microcomputers. It explains that supercomputers are the most powerful for processing large datasets. Mainframes are less powerful than supercomputers and are used for applications like banking. Midrange computers include minicomputers and servers. Microcomputers range from desktop PCs to mobile devices. The CPU and computer memory are also described.
This document discusses different types of secondary storage devices and their characteristics. It begins by explaining the limitations of primary storage and need for secondary storage. It then classifies commonly used secondary storage devices as sequential-access devices like magnetic tapes and random-access devices like magnetic disks. Specific device details covered include half-inch tape reels, tape cartridges, floppy disks, hard disks, CDs, DVDs, flash drives and memory cards. The document concludes by presenting the storage hierarchy from fastest and most expensive to slowest and least expensive storage.
The document discusses various methods for storing and retrieving images, including tape drives, hard disks, optical discs like CDs and DVDs, and removable media like zip disks. It describes the basic technology behind each storage type, their capacities and transfer speeds, common formats, and advantages and limitations. Tape drives provide large storage capacities but slow sequential access, while hard disks and optical discs offer faster random access but have more limited capacities. Removable disks like zip disks also provide portable storage.
Hard disk & Optical disk (college group project)Vshal_Rai
- Hard disk drives (HDDs) are devices used for digital data storage. They consist of rapidly rotating discs coated with magnetic material. Magnetic heads write data to and read data from the disc surfaces.
- HDDs were first introduced in 1956 and have since decreased dramatically in size and cost, becoming standard in personal computers by the late 1980s. Capacities have also increased greatly, with modern HDDs capable of storing terabytes of data.
- Optical discs like CDs and DVDs store data in the form of pits and lands on a reflective surface. They were invented in the late 1950s and early 1960s and are now commonly used to store music, video, and computer programs and data.
These Notes from the class of BS EDUCATION 1st Semester (Spring) Session 2023-2027 Teacher :Ch Naveed Afzal
semester started in march 2023 and end in july 2023
The document discusses various data storage devices. It describes floppy disks, CDs, DVDs, hard disks, USB flash drives, and different types of ROM and RAM. Floppy disks can store up to 1.4 MB of data but newer ones can store up to 250MB. CDs standardly hold up to 80 minutes of audio or 700MB of data. DVDs have significantly higher storage capacity than CDs, able to hold up to 17GB. Hard disks use spinning magnetic disks to store data and have faster access times than removable media. USB flash drives have flash memory and are small, portable, and write/rewrite data. The different types of ROM and RAM each have their own characteristics for
Secondary storage devices store information even when a computer is powered off. Common secondary storage devices include floppy disks, hard disks, magnetic tapes, flash drives, and optical disks. Magnetic tapes and disks are sequential access devices that read/write data in sequence, while hard disks and optical disks are direct access devices that allow random access to data. Secondary storage provides large storage capacity at lower costs than primary storage and is used to store programs and data.
Secondary storage devices such as hard disks, CDs, USB drives, and Blu-ray discs are used for bulk storage of data with large capacities and transfer data to main memory for processing. Hard disks provide fast storage and high capacities, storing data on magnetic disks accessed by read/write heads. CDs and Blu-ray discs use optical technology to store digital data in pits encoded in spiral tracks, with Blu-ray using a blue laser to achieve higher densities. USB drives are portable flash memory devices that can easily transfer data between computers. Secondary storage is cheaper than main memory and has slower access times.
Floppy disks, CDs, DVDs, tape drives, flash memory, and memory cards are described as common data storage devices. Floppy disks were widely used in the late 20th century but have been largely replaced by methods with greater storage capacities like USB flash drives, external hard drives, and cloud storage. CDs and DVDs introduced rewritable formats like CD-RW and DVD-RW that allowed erasing and rewriting data multiple times compared to write-once formats. Tape drives provide sequential access storage for offline archival, while solid state flash memories like memory cards have faster random access.
This document provides an overview of various data storage technologies and devices used in client-server systems, including magnetic disks, tapes, CD-ROMs, WORM disks, optical disks, RAID configurations, network protection devices, power protection devices, and remote system management. It describes the basic workings and purposes of these different components that are crucial for reliable data storage and system uptime in client-server computing environments.
COMPACT PRESERVATION OF SCRAMBLED CD-ROM DATAijcsit
When preserving CD-ROM discs, data sectors are often read in a so-called “scrambled mode” in order to preserve as much data as possible. This scrambled data is later unscrambled and further processed into a standard CD-ROM disc image. The process of converting the scrambled data into a standard CD-ROM disc image is potentially lossy, but standard CD-ROM disc images exhibit much higher software compatibility and have greater usability compared to the scrambled data from which they are derived. Consequently, for preservation purposes, it is often necessary to store both the scrambled data and the corresponding standard disc image, resulting in greatly increased storage demands compared to storing just one or the other. Here, a method that enables compact storage of scrambled data alongside the corresponding (unscrambled) standard CD-ROM disc image is introduced. The method produces a compact representation of the scrambled data that is derived from the unscrambled disc image. The method allows for (1) storage of the standard unscrambled disc image in unmodified form, (2) easy reconstruction of the scrambled data as needed, and (3) a substantial space savings (in the typical case) compared to storing the scrambled data using standard data compression techniques.
This document provides an overview of computer storage fundamentals, including primary and secondary storage. It discusses the characteristics and uses of different types of primary storage (RAM and ROM) and secondary storage devices (floppy disks, hard disks, optical disks, USB flash drives, and magnetic tapes). RAM is temporary and volatile, holding data currently being processed, while ROM is permanent and non-volatile. Secondary storage devices are used to permanently store large amounts of non-essential data and include magnetic and optical media with varying speeds and capacities.
Similar to 1.optical storage read and write.pdf (20)
A Strategic Approach: GenAI in EducationPeter Windle
Artificial Intelligence (AI) technologies such as Generative AI, Image Generators and Large Language Models have had a dramatic impact on teaching, learning and assessment over the past 18 months. The most immediate threat AI posed was to Academic Integrity with Higher Education Institutes (HEIs) focusing their efforts on combating the use of GenAI in assessment. Guidelines were developed for staff and students, policies put in place too. Innovative educators have forged paths in the use of Generative AI for teaching, learning and assessments leading to pockets of transformation springing up across HEIs, often with little or no top-down guidance, support or direction.
This Gasta posits a strategic approach to integrating AI into HEIs to prepare staff, students and the curriculum for an evolving world and workplace. We will highlight the advantages of working with these technologies beyond the realm of teaching, learning and assessment by considering prompt engineering skills, industry impact, curriculum changes, and the need for staff upskilling. In contrast, not engaging strategically with Generative AI poses risks, including falling behind peers, missed opportunities and failing to ensure our graduates remain employable. The rapid evolution of AI technologies necessitates a proactive and strategic approach if we are to remain relevant.
Assessment and Planning in Educational technology.pptxKavitha Krishnan
In an education system, it is understood that assessment is only for the students, but on the other hand, the Assessment of teachers is also an important aspect of the education system that ensures teachers are providing high-quality instruction to students. The assessment process can be used to provide feedback and support for professional development, to inform decisions about teacher retention or promotion, or to evaluate teacher effectiveness for accountability purposes.
This slide is special for master students (MIBS & MIFB) in UUM. Also useful for readers who are interested in the topic of contemporary Islamic banking.
Thinking of getting a dog? Be aware that breeds like Pit Bulls, Rottweilers, and German Shepherds can be loyal and dangerous. Proper training and socialization are crucial to preventing aggressive behaviors. Ensure safety by understanding their needs and always supervising interactions. Stay safe, and enjoy your furry friends!
Introduction to AI for Nonprofits with Tapp NetworkTechSoup
Dive into the world of AI! Experts Jon Hill and Tareq Monaur will guide you through AI's role in enhancing nonprofit websites and basic marketing strategies, making it easy to understand and apply.
A review of the growth of the Israel Genealogy Research Association Database Collection for the last 12 months. Our collection is now passed the 3 million mark and still growing. See which archives have contributed the most. See the different types of records we have, and which years have had records added. You can also see what we have for the future.
বাংলাদেশের অর্থনৈতিক সমীক্ষা ২০২৪ [Bangladesh Economic Review 2024 Bangla.pdf] কম্পিউটার , ট্যাব ও স্মার্ট ফোন ভার্সন সহ সম্পূর্ণ বাংলা ই-বুক বা pdf বই " সুচিপত্র ...বুকমার্ক মেনু 🔖 ও হাইপার লিংক মেনু 📝👆 যুক্ত ..
আমাদের সবার জন্য খুব খুব গুরুত্বপূর্ণ একটি বই ..বিসিএস, ব্যাংক, ইউনিভার্সিটি ভর্তি ও যে কোন প্রতিযোগিতা মূলক পরীক্ষার জন্য এর খুব ইম্পরট্যান্ট একটি বিষয় ...তাছাড়া বাংলাদেশের সাম্প্রতিক যে কোন ডাটা বা তথ্য এই বইতে পাবেন ...
তাই একজন নাগরিক হিসাবে এই তথ্য গুলো আপনার জানা প্রয়োজন ...।
বিসিএস ও ব্যাংক এর লিখিত পরীক্ষা ...+এছাড়া মাধ্যমিক ও উচ্চমাধ্যমিকের স্টুডেন্টদের জন্য অনেক কাজে আসবে ...
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Macroeconomics- Movie Location
This will be used as part of your Personal Professional Portfolio once graded.
Objective:
Prepare a presentation or a paper using research, basic comparative analysis, data organization and application of economic information. You will make an informed assessment of an economic climate outside of the United States to accomplish an entertainment industry objective.
ISO/IEC 27001, ISO/IEC 42001, and GDPR: Best Practices for Implementation and...PECB
Denis is a dynamic and results-driven Chief Information Officer (CIO) with a distinguished career spanning information systems analysis and technical project management. With a proven track record of spearheading the design and delivery of cutting-edge Information Management solutions, he has consistently elevated business operations, streamlined reporting functions, and maximized process efficiency.
Certified as an ISO/IEC 27001: Information Security Management Systems (ISMS) Lead Implementer, Data Protection Officer, and Cyber Risks Analyst, Denis brings a heightened focus on data security, privacy, and cyber resilience to every endeavor.
His expertise extends across a diverse spectrum of reporting, database, and web development applications, underpinned by an exceptional grasp of data storage and virtualization technologies. His proficiency in application testing, database administration, and data cleansing ensures seamless execution of complex projects.
What sets Denis apart is his comprehensive understanding of Business and Systems Analysis technologies, honed through involvement in all phases of the Software Development Lifecycle (SDLC). From meticulous requirements gathering to precise analysis, innovative design, rigorous development, thorough testing, and successful implementation, he has consistently delivered exceptional results.
Throughout his career, he has taken on multifaceted roles, from leading technical project management teams to owning solutions that drive operational excellence. His conscientious and proactive approach is unwavering, whether he is working independently or collaboratively within a team. His ability to connect with colleagues on a personal level underscores his commitment to fostering a harmonious and productive workplace environment.
Date: May 29, 2024
Tags: Information Security, ISO/IEC 27001, ISO/IEC 42001, Artificial Intelligence, GDPR
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This presentation includes basic of PCOS their pathology and treatment and also Ayurveda correlation of PCOS and Ayurvedic line of treatment mentioned in classics.
1. Computer Peripherals
School of Computer Engineering
Nanyang Technological University
Singapore
These notes are part of a 3rd year undergraduate course called "Computer Peripherals", taught at Nanyang Technological University
School of Computer Engineering in Singapore, and developed by Associate Professor Kwoh Chee Keong. The course covered
various topics relevant to modern computers (at that time), such as displays, buses, printers, keyboards, storage devices etc... The
course is no longer running, but these notes have been provided courtesy of him although the material has been compiled from
various sources and various people. I do not claim any copyright or ownership of this work; third parties downloading the material
agree to not assert any copyright on the material. If you use this for any commercial purpose, I hope you would remember where you
found it.
Further reading is suggested at the end of each chapter, however you are recommended to consider a much more modern alternative
reference text as follows:
Computer Architecture: an embedded approach
Ian McLoughlin
McGraw-Hill 2011
2. Chapter 12. Optical Disks
After the human memory, optical storage is perhaps the oldest storage technology in
use. When cavemen started making scratches on the walls of their caves, we have not only an
application of write-once ready-many (WORM) technology, but a data encoding method as
well! However the modern optical storage devices have a relatively short history as the first
laser disk was only demonstrated in 1972. This was the 12-inch Laservision, a video disk in
which the video signal was stored in an analog form similar to the present video cassette
recorders. Later in 1975, Philips together with Sony defined the standard for the 5-in audio
CD (compact disc). This is a read-only device, but the audio information is stored digitally.
The EFM (eight-to-fourteen modulation) coding scheme invented by Philips continues to
generate income by way of license and royalty fees that contributes a significant proportion to
the total budget of their R&D activities. Optimem demonstrated in 1977 the first 12-inch
writeable (once) disk (WORM). So far the devices developed were targeted at the consumer
audio-visual market.
In 1980, Philips and Sony introduced a version of the CD that is used for storing digital
data for computer applications. As this acts as a memory device, it was called the CD-ROM.
Finally in 1987, Sony demonstrated the erasable and rewritable 5.25-inch optical disk drive.
Recently products became available enabling the user to create his own CD-ROM using a
write-once disk.
12.1. Types of Optical Disk
Although there are many different types of optical disks, they can be grouped into three main
categories.
1. Read-only memory (ROM) disks, like the audio CD, are used for the distribution of
standard program and data files. These are mass-produced by mechanical pressing
from a master die. The information is actually stored as physical indentations on
the surface of the CD. Recently low-cost equipment has been introduced in the
market to make one-off CD-ROMs, putting them into the next category.
2. Write-once read-many (WORM) disks: Some optical disks can be recorded once.
The information stored on the disk cannot be changed or erased. Generally the
disk has a thin reflective film deposited on the surface. A strong laser beam is
focused on selected spots on the surface and pulsed. The energy melts the film at
that point, producing a non-reflective void. In the read mode, a low power laser is
directed at the disk. and the bit information is recovered by sensing the presence
or absence of a reflected beam from the disk.
3. Re-writeable, write-many read-many (WMRM) disks, just like the magnetic
storage disks, allows information to be recorded and erased many times. Usually,
there is a separate erase cycle although this may be transparent to the user. Some
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3. Optical Disks 2
modern devices have this accomplished with one over-write cycle. These devices
are also called direct-read-after-write (DRAW) disks.
12.2. Read-Only Storage
The CD-ROM, together with the audio compact disk are examples of technologically
advanced products that have been mass-produced and made readily available to the general
public. For the computer industry, the read-only CD-ROM is gaining importance as a delivery
medium for software. The large storage capacity and low cost of manufacture makes it a very
attractive means of distributing software which is getting larger all the time. Also machine-
readable documentation can be included on the same disk or on a separate disk. Software
available on CD-ROMs now include many games which have large graphics and audio files,
graphics software with clip-art, and operating systems like Unix and OS/2.
Figure 12.1. Pits and land representing data bits in a CD-ROM.
The CD is a 120-mm diameter polycarbonate disk with a thickness of 1.2 mm. The disk
is coated with a reflective aluminium layer on which a sequence of 'pits' are placed in a spiral
track. To prevent corrosion and physical damage, a protective layer covers the reflective
surface. In operation, as shown in Figure 12.1, a low power laser beam is focused through the
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4. Optical Disks 3
transparent protective layer and the reflected beam is detected. Everywhere there is a pit, the
beam is not reflected so that binary information can be represented as a series of pits and lands
along the track.
The basic performance of CDs and CD-ROMs are given in Table 12.1. As it is an
adaptation of the audio CD, the CD-ROM can be reproduced at very low cost, and can be read
and re-read without any degradation. There are however some limitations and inefficiencies.
<<The standard audio CD block contains 672 data bytes. Computers normally work
with some multiple of 512 bytes per block. In the CD-ROM, blocks of 2048 data bytes are
used and some 588 bytes are 'wasted' This decreases the data capacity and the data transfer
rate. >> to be replaced by p 216 of cunningham.
Calculating Data Capacity
Blank recordable CD-R and CD-RW discs are available in two capacities: 74 minutes
(both CD-R and CD-RW) and 80 minutes (CD-R only at this time).
So, if we do the math:
74 min x (60 sec) x (75 sectors) x (2 kbytes) = 666,000 kilobytes
= 650 megabytes
80 min x (60 sec) x (75 sectors) x (2 kbytes) = 720,000 kilobytes
= 703 megabytes
Factory-recorded CDs can be made to hold a little more data.
The actual capacities of blank discs can vary slightly; some 74-minute discs can hold up
to two minutes more than their stated capacity. However, this is not likely to be evident on the
packaging; you will have to find it out by direct experience, or by asking other CD-R users.
Constant linear velocity (CLV) format
The constant linear velocity (CLV) format requires the rotational speed to be changed as
the radial position of the read head changes. This can take up to a second for full stroke
movement. Still, the market has readily accepted the CD-ROM as a very convenient and
secure way for delivering software.
Standard ECMA/TC15/86/16 [1986]
Disk diameter 120 mm, single-sided.
Data capacity 650 Mbytes of data plus overhead, 170,000 equivalent
pages
Format Constant linear velocity, embedded servo.
Scanning velocity 1.2 m/s, with up to 25,000 spiral tracks.
Rotational speed approx. 200 rpm @ OD, 500 rpm @ ID.
Access time 600 ms, average.
Data rate 2 Mbits/s.
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5. Optical Disks 4
EDAC strategy CIRC (cross-interleaved Reed-Solomon code) ECC.
Table 12.1. Characteristics of the CD-ROM.
12.3. Write-Once Systems
The photographic process is an obvious write-once only optical recording system. However,
such methods, including the use of photographic films, photoresists and photopolymers
require development or some other similar form of post-processing. Other non-erasable
technologies make use of ablative thin films and phase-change media. The recording
mechanism is permanent and cannot be reversed.
In ablative recording, spots on a thin film of metal, bonded to the disk substrate, is
melted to form a hole. Metal films like tellurium, bismuth, selenium and other alloys with low
melting points are used. In high speed recording, the energy of the laser beam is sufficient to
vaporize the metal, hence the term ablative. Whether melted or vaporized, the hole size must
be large enough so that surface tension and reflow does not cause the void to be unstable.
Dye/polymer recording, uses ablation to form marks in light-absorbing organic films by
heat. Apart from the vaporization of material, the pressurized vapor also pushes the soft
polymer away to form a clearly defined pit.
Phase-change media can exist in two or more stable structural states. The material is
manufactured in a metastable state. When a mark is required, heat is applied at the required bit
cell with the laser. This heats the region up and the material is allowed to anneal into a more
stable state. For example the material may be deposited in the amorphous state. The heat cycle
causes the material to anneal into the crystalline state. Usually the crystalline state is more
reflective and this property is used in reading out the stored data. The material properties have
to be carefully selected so that the states remains stable even at all expected storage
temperatures. Unlike the rewritable systems, this phase-change cannot be reversed.
Write-once systems are particularly suitable for archival storage. Recently low-cost
systems have been introduced into the market which enable users to create their own
CD-ROMs.
Apart from disk systems, write-once storage devices are appearing in the form of smart
cards and stored value debit cards where a complete and non-erasable history of all
transactions can be kept for audit purposes.
12.4. Rewritable Optical Storage
With the development of the erasable/rewritable optical disk, the most obvious limitation of
optical storage systems is removed. Optical disks can now functionally replace other recording
storage media. In applications where large amounts of data have to be stored, but read/write
access times are not stringent, this is in fact beginning to take place. At this point, it should be
noted that the 'floptical' (floppy-optical) drives, which is also known as SuperDrive or LS120,
do not use optical storage techniques. The optical portion of the name comes from the fact that
optical tracking is used in the positioning of the head, enabling a much higher track density
and total storage. Magnetic recording is still used for data storage.
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6. Optical Disks 5
At present the magneto-optical recording is the main technology used in WMRM (write-
many read-many) disks. Other methods have been demonstrated and one making use of
reversible phase-change media appears quite promising.
12.4.1. Thermomagneto-optics
When a magnetized piece of iron is heated, a temperature is reached above which the
magnetization is lost. Some materials have the property that at normal room temperature they
are very resistant to any changes in the magnetic domain structure, i.e. the material exhibits a
high coercivity. A high applied field is needed to change its magnetic pattern. However when
the temperature is raised above a certain characteristic value, called the Curie temperature
Tcurie, the magnetic structure becomes disoriented and the coercivity disappears.
Figure 12.2. Thermomagneto-optical recording.
In the magneto-optical (M-O) storage device, the disk is coated with a layer of M-O
material, with a Curie temperature of about 200°C. In the 'blank' state the material has an
initial magnetization, say downwards, representng all zeroes. During the write cycle, a
magnetic field in the upwards direction is applied to the region and a high power laser is
focused onto the spot where the '1' bit data is to be written. This spot is quickly raised above
Tcurie, lowering the coercivity. As the material cools, the magnetic domains are realigned
according to the externally applied field. Figure 12.2 illustrates the arrangement of the laser
and externally applied magnetic field.
The written information can be erased by repeating the write process with the external
field reversed. At the present most systems uses a separate erase cycle. Compared with normal
magnetic recording techniques this is a disadvantage as it means that each re-write operation
requires at least two revolutions of the disk. Intensive efforts are under way to develop a
reliable over-write materials and technology.
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7. Optical Disks 6
Figure 12.3. Kerr rotation from vertical magnetization..
To read the stored information from the optical disk, we make use of the Kerr effect.
This is shown in Figure 12.3. A plane polarized beam is directed at the M-O layer and the
reflected beam is detected. Comparison of the plane of polarization between the incident and
reflected beam shows that the reflected beam has undergone a small angle of rotation. The
direction of rotation depends on the direction of the vertical magnetization of the spot the
beam is focused on. For example, if initially the direction of magnetization is downwards,
representing binary '0', the polarization is rotated 20° anti-clockwise. When a '1' is written, the
direction of polarization is reversed to point upwards. The beam reflected from this region
will have the plane of polarization rotated 20° in the clockwise direction. In this way, the
direction of magnetization, which is a representation of the stored information can be
detected.
12.4.2. Magneto-optical systems
Figure 12.4 illustrates the essential features of a M-O disk drive. The laser diode has
two power levels, high power to raise the temperature of the M-O layer above the Curie
temperature, and a lower power beam for reading. The laser beam is passed through a
diffraction grating and collimator lens into the polarizing beam splitter cube (PBSC). From
this direction most of the beam is transmitted to the movable mirror which directs it onto the
selected track on the disk. The polarized beam passes through a variable-phase plate in both
directions. When the plane-polarized incident beam interacts with the M-O material, a
component normal the plane of polarization is produced. The variable-phase takes this
elliptically polarized reflected beam and converts it in two linearly-polarized beams, aligned
with the parallel and perpendicular axes. This is reflected back to the first PBSC which now
reflects the composite beam down to the second PBSC where the two beams are split, one
being transmitted and the other reflected. The intensities of these two beams are detected
differentially to give the direction of rotation, hence the direction of magnetization and the bit
information.
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8. Optical Disks 7
Figure 12.4. M-O disk drive.
In the write mode, the input signal is applied to the opto-modulator which controls the
intensity of the laser beam directed at the disk. For a write of a '1', the intensity is sufficient to
raise the temperature of the M-O material above Tcurie.
12.4.3. Phase-change recording
Phase-change recording makes use of the discovery that many materials can exist in several
crystalline phases. Generally the most common phase has the lowest energy state, but the
other phases can occur at a local activation energy minima. The change in phase often causes
changes in some optical characteristics such as refractive index or colour. These changes are
exploited in phase-change recording. The laser beam is used to rapidly heat a small region
which is then quenched quickly into its new state. For erasure, the region is heated and
allowed to cool slowly, annealing the material back into the original state. To read the data, a
much lower power laser beam is used. A typical phase diagram is shown in Figure 12.5, and
Table 12.2 lists the basic requirements for erasable phase-change materials.
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9. Optical Disks 8
Figure 12.5. Phase diagram of phase-change material.
Characteristics Function
Refractive index change Optical contrast between crystalline and
amorphous regions
Moderate thermal conductivity Enables rapid cooling and quenching
Low melting point Tmelt High sensitivity
Rapid annealing below Tmelt Easy erasure
High activation energy for annealing Stable data storage
Density compatibility Low physical stress
Table 12.2. Erasable phase-change material requirements.
12.5. Data Storage Formats
Like the magnetic disks, three different formats are used to organise data on the optical disk.
These are shown in Figure 12.6.
The constant linear velocity (CLV) format optimizes utilisation of the usable recording
area by having an uniform recording density throughout the disk. By maintaining the linear
velocity constant, the recording density is kept constant. Data are stored in one continuous
track that spirals from the circumference inwards to the centre. As the tracks moves inwards,
the radius decreases and to maintain the same linear velocity the disk must spin faster. CLV is
best suited for sequential access applications such as in the CD audio disk and as a
replacement for magnetic tape in for archive and backups. In most applications of CD-ROM,
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10. Optical Disks 9
this is generally acceptable, where the information contained are usually programs which have
to be installed or loaded sequentially. Trying to directly access a specific block of information
is slow as apart from the movement of the read head mechanism, the rotational speed of the
disk has to change also. CD-ROMs and some WORM devices use the CLV format.
Zoned constant
angular velocity
Constant angular velocity
Constant linear velocity
Figure 12.6. Disk recording layouts.
Magnetic hard and floppy disks normally use the constant angular velocity (CAV)
format for the layout of the tracks and sectors. With concentric tracks and a fixed number of
sectors per track, direct access to any specific sectors depends only on the seek delay. The
rotation of the disk is at a high constant speed, which also keeps the latency time down. An
ANSI/ISO standard has been defined for rewritable optical disks using this format.
Performance characteristics Philips LaserDrive Maxtor Tahiti
Disk, 20sided 12 cm M-O, ISO 12 cm M-O
Capacity, per side 327 MB 298 MB, CAV
466 MB, ZCAV
Bytes/Sector 512 512/1024
Typical bit density 25,000 bpi.
Track/pitch density 1.6 mm 17,000 tpi.
Encoding method: RLL (4,15) RLL, (2,7)
Average access time: 70 msec incl latency 35 msec seek
Spindle speed: 1800 rpm CAV 2200 rpm CAV, ZCAV
Error rate with ECC 10-12 bytes
Table 12.3. Typical performance of M-O disks.
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11. Optical Disks 10
Zoned constant angular velocity (ZCAV) reduces the inefficiencies of the CAV format
by dividing the disk into typically five zones. The maximum recording density is used at the
inner radius of each zone, resulting in a different number of sectors per track between the
zones. The increased complexity of the controller is justified by the improvement of over 40%
in storage capacity. Presently no industry standard has been defined for ZCAV formats. In the
advanced magnetic disks where the platters are fixed, this is not a problem, but with
removable optical disk cartridges, interchangeability amongst M-O drives has not been
realized. For example, the Maxtor Tahiti M-O drive supports both CAV and ZCAV. 327
Mbytes of data can be stored in the ANSI CAV format, whereas using the Maxtor proprietary
ZCAV format, the same disk can hold as much as 500 Mbytes. Brief specifications of two
M-O drives are reproduced in Table 12.3 as examples.
12.6. Focus and Tracking
In the magnetic disk, sophisticated servo systems are used to keep the head aligned with the
track being read or written. The flying height of the head above the media surface is
determined by the aerodynamic design, springs and the surface velocity. In optical disks,
servos are required to position accurately the head on the selected track and also to ensure that
the laser beam is properly focused on the reflective film.
The tolerances in optical disks are typically ±0.1 mm for tracking and ±0.5 mm for the
focusing of the optical read / write head. Usually the same laser beam that is used for the
read/write operation is used to accurately sense the head position. The tracking and focusing
errors are processed by complex electro-mechanical servo systems, often incorporating digital
signal processors.
12.6.1. Focus sensors
Figure 12.7. Focusing error sensing using the Foucault knife-edge.
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12. Optical Disks 11
Referring to Figure 12.7, it will be seen that when the focus is perfect, sensors A and B
will detect equal amounts of light, but when the media is slightly out of focus, there will be a
difference in the amount of light falling on sensors A or B. This error signal can be used as the
input to the servo system for focusing the laser beam. Other focus sensors that operate with
collimated beams are the half-aperture sensors and the astigmatic focus sensors. Although the
above discussion depends on the use of a collimated (parallel) beam, the same effect is
observed even when there is some divergence in the beam.
12.6.2. Tracking sensors
The audio LP record uses the groove to constrain the pick-up stylus to stay in the track. In
optical disks, there is no physical contact between the optical stylus and the disk, but one
important method of tracking makes use of tracking grooves on the disk.
Figure 12.8. Track positioning sensor.
As shown in Figure 12.8 the tracks on the disk form grooves on the surface. The
wavelength of the lasers used on optical disk is about 0.8 µm, and the grooves are spaced 1.6
µm apart. When the incident beam is directed at the surface, apart from the primary reflected
beam located at the angle of reflection, the grooves cause the beam to be diffracted, with
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13. Optical Disks 12
components reinforcing the primary reflected beam. A diffraction pattern is produced which is
symmetrical when the beam is exactly aligned on the groove. If there is a small deviation from
the track, the pattern changes, and the intensity of the light detected at a split sensor becomes
unbalanced. This is used as the error signal input to the tracking servo system.
12.7. Defect Management
Error detection and correction techniques used in optical storage systems are essentially the
same as those used for magnetic disks. However, because of the much higher density of
recording, the optical marks are smaller. The laser is working at just a slightly longer
wavelength than white light and it is not possible to see the marks made by the laser beam
using an ordinary optical microscope. Defects like dust, scratches, voids, which may not cause
any problems in magnetic media are now relatively two orders of magnitude larger in optical
media. Bit error rates (BER) of 10-8 are readily achieved with magnetic media and certified
defect-free diskettes, tapes and disk are normal. With optical media, current manufacturing
processes can only achieve a BER of 10-6.
Error management strategies have already been discussed in Chapter 8. With erasable
disks the same defect management procedures can be used. The media is formatted, and a
defect map maintained to identify defective sectors which are re-vectored. A complication
arises with WORM disks where the medium can only be written once. It is not possible to
perform a verification of the medium, and the presence of defects is detected only during the
actual write operation.
During the operation of WORM drives, a direct read after write is performed, and if the
a block of data could not be verified, it is re-written in the next block. This strategy is
somewhat similar to that used in QIC tapes, except that to conserve media, and because of the
direct access capability of the disk drive no additional successive blocks need to be written.
The verification stage requires a second pass of the sector under the read, slowing down the
whole process. In some WORM drives a complex optical system is used where verification is
made during the same pass as the write operation by interleaving a second low power laser
pulse to read the bit immediately.
12.8 CD versus DVD
Feature CD format DVD format
Disk diameter 120 mm (5 in) 120 mm (5 in)
Basic structure One 1.2-mm substrate Two 0.6-mm substrates
DVD-5: 4.7 GB
(single-sided, single layer)
DVD-9: 8.5 GB
(single-sided, two layers)
DVD-18: 17 GB
(double-sided, single layer)
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14. Optical Disks 13
Minimum pit
Length
0.83 µm 0.4 µm
Laser wavelength 780 nm 635 to 650 nm
Numerical aperture
(n sinθ)
0.45 0.6
Areal data density 0.68 Gbit/in2
3.28 Gbit/in2
Track density 16,000 tpi 34,000 tpi
Linear bit density 43,000 bit/in 96,000 bit/in
Data rate (for same
rpm)
Variable,
4.8 Mbit/s max
Variable,
11 Mbit/s max
Refer to “DVD technology: The new paradigm in optical storage.” by Micheal Elphick
in Data Storage, January 1997.
12.9. Conclusions
CD-ROM, WORM and rewritable optical disk are effective devices for the storage of large
programs and data files. With the increasing use of multimedia applications where sound,
graphics and video are used, the data files used are often several Mbytes in size. The challenge
is to be able to deliver these large amounts of data to the computing elements at a rate capable
of supporting real-time audio, video and animation graphics.
Development is proceeding rapidly in several fronts. There is a constant search for
improvements in media that have faster response, are more stable and can reliably undergo
many cycles of erasures. To increase the storage density, researchers are experimenting with
shorter wavelength lasers in the blue range. Compared to the magnetic Winchester disks,
access times are much longer and developments in servo systems using DSP techniques are
needed for the focusing and tracking systems.
The lack of a standard M-O format for 5.25 in. disks presents an obstacle to the growth
of the market. Some of the newer drives, particularly those using the 3.5 in. format are being
developed with the capability to handle CD-ROM, WORM, WMRM and P-ROM (Partial
ROM), where some space at the end of each block is available for user written data on a
compatible CD-ROM.
The PCMCIA is now well accepted as an interface and peripheral device standard.
There are opportunities for new product development of optical storage products that will
conform to this standard. These devices could use either rotating disks or stationary cards.
There could be demand for 'smart cards' that would hold many Mbytes of data, for example,
the contents of a book complete with illustrations.
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