Cyberlaw 2.0

This Article outlines two versions of cyberlaw, The first, characteristic of the scholarship of the late 1990s, is typified by a borclerless Internet and national laws that cease to have effect at their real-space borders, the regulatory power of code, and the virtue of selfregulatory solutions to Internet and e-commerce issues. In Cybet\u27law 2.0, the borderless Internet becomes bordered, bordered laws become borderless. the regulation of code becomes regulated code, and selfregulation becomes industry consultation, as government shifts toward a more traditional regulatory approach. The Article assesses each of these changes, calling attention to recent developments in copyright law, domain name dispute resolution, privacy, and Internet governance. At the heart of each is the question of the appropriate governmental role in Internet regulation and the need for cyberlaw to reconcile how government and regulation fit within the tensions of ever-changing technologies

Looking at The Future of Canadian Copyright in The Rear View Mirror

"L’auteur présente une analyse générale de l’évolution historique et des développements récents du régime des droits d’auteur au Canada. Avec le développement des nouvelles technologies de l’information, et plus spécifiquement de l’Internet, le régime canadien des droits d’auteur nécessiterait d’importantes réformes. L’auteur déplore toutefois les modifications récentes issues de la loi C-60. En effet, selon lui, ces changements ne correspondent pas au régime international proposé par l’Organisation Mondiale de Propriété Intellectuelle. En fait, ceux-ci cadrent beaucoup plus avec la perspective américaine de protection limitative des droits d’auteur. Michael Geist trace d’abord l’historique du développement du régime de protection des droits d’auteur au Canada. Il souligne notamment les modifications législatives importantes de la fin des années 1980 et 1990 qui visaient à renforcer les règles de reconnaissance et de protection des droits que les auteurs canadiens possèdent sur leurs œuvres. Parallèlement, à ces modifications législatives, la Cour Suprême du Canada s’est aussi prononcée sur la question des droits d’auteur en interprétant limitativement la portée de ce régime, facilitant ainsi l’accès des œuvres artistiques au domaine public. L’auteur souligne les divergences et les contradictions entre la conception législative et celle jurisprudentielle de la fonction du régime canadien des droits d’auteur. Le législateur canadien a récemment proposé une nouvelle modification du régime de droits d’auteurs qui consisterait en l’extension des délais obligatoire avant qu’une œuvre couverte par le régime ne soit incluse dans le domaine public. Michael Geist s’oppose à une telle modification et soutient qu’elle entraînerait de nombreuses conséquences négatives pour les auteurs et les artistes canadiens. En effet, cette modification limiterait l’accès des auteurs aux oeuvres antérieures, elle entraverait les opportunités et les capacités commerciales des œuvres canadiennes et restreindrait les domaines de recherche académique. L’auteur aborde par la suite la problématique reliée aux ""Mesures de Protection Techniques"" et à la législation qui les encadre. En analysant les problèmes causés par ces mesures aux États-Unis, il présente leurs effets nuisibles pour les domaines fondamentaux de la liberté de parole et de la recherche académique. Les réformes possibles du régime canadien des droits d’auteur se situent dans une perspective plus ouverte du régime de protection et de promotion des œuvres canadiennes. Ces réformes auraient l’avantage de promouvoir et de protéger les œuvres canadiennes tout en évitant les problèmes causés par les mesures trop limitatives. À ce sujet, l’auteur propose l’établissement d’une bibliothèque digitale nationale, l’abrogation des droits d’auteur de la couronne et un nouveau régime permettant l’utilisation du matériel radiodiffusé de la Société Radio-Canada."Author Michael Geist presents a general analysis of the evolution and the recent developments of the Canadian copyright regime. With the development of the Internet and other communication technologies, the current Canadian copyright law needed a significant reform. However, the author is critical of the recent modifications introduced through bill C-60 and holds that they do not correspond with the international set of norms proposed by the World Intellectual Property Organization. In fact, these modifications display many characteristics of the restrictive and limitative copyright regime of the United States. The first part of the article presents the evolution of the copyright protection regime in Canada. Notably, he defines the significant legislative modifications of the 1980’s and 1990’s designed to recognize and increase the legal protection of original artistic and academic works. The Supreme Court of Canada also entered the debate by limiting the application of the copyright regime, thus facilitating the access of original works to the public domain. The author underlines the differences between the legislative and the jurisprudential conceptions of the scope of the Canadian copyright regime. The Canadian legislator recently proposed a new modification to the current copyright regime. This modification extend the mandatory period before an original work can be integrated into the public domain. The author is critical of such a modification and holds that it would bring dire consequences for the Canadian authors and artists. Indeed, this modification could limit the access to prior work, thus limiting the commercial opportunity and restraining fields of academic research. The author then analyses the problems generated by anti-circumvention legislations in the United Sates. He explains how such legislations limit the fundamental right of free speech and the potential of academic research. Future reforms of the Canadian copyright regime should be made through an open and inclusive perspective in order to protect, as well as promote, original Canadian works, without the negative effects of restrictive copyright regimes. To this end, the author proposes certain measures, such as the establishment of a National Digital Library, eliminating crown copyright and the development of new rights to use CBC content

SpaceCube Mini

This version of the SpaceCube will be a full-fledged, onboard space processing system capable of 2500+ MIPS, and featuring a number of plug-andplay gigabit and standard interfaces, all in a condensed 3x3x3 form factor [less than 10 watts and less than 3 lb (approximately equal to 1.4 kg)]. The main processing engine is the Xilinx SIRF radiation- hardened-by-design Virtex-5 FX-130T field-programmable gate array (FPGA). Even as the SpaceCube 2.0 version (currently under test) is being targeted as the platform of choice for a number of the upcoming Earth Science Decadal Survey missions, GSFC has been contacted by customers who wish to see a system that incorporates key features of the version 2.0 architecture in an even smaller form factor. In order to fulfill that need, the SpaceCube Mini is being designed, and will be a very compact and low-power system. A similar flight system with this combination of small size, low power, low cost, adaptability, and extremely high processing power does not otherwise exist, and the SpaceCube Mini will be of tremendous benefit to GSFC and its partners. The SpaceCube Mini will utilize space-grade components. The primary processing engine of the Mini is the Xilinx Virtex-5 SIRF FX-130T radiation-hardened-by-design FPGA for critical flight applications in high-radiation environments. The Mini can also be equipped with a commercial Xilinx Virtex-5 FPGA with integrated PowerPCs for a low-cost, high-power computing platform for use in the relatively radiation- benign LEOs (low-Earth orbits). In either case, this version of the Space-Cube will weigh less than 3 pounds (.1.4 kg), conform to the CubeSat form-factor (10x10x10 cm), and will be low power (less than 10 watts for typical applications). The SpaceCube Mini will have a radiation-hardened Aeroflex FPGA for configuring and scrubbing the Xilinx FPGA by utilizing the onboard FLASH memory to store the configuration files. The FLASH memory will also be used for storing algorithm and application code for the PowerPCs and the Xilinx FPGA. In addition, it will feature highspeed DDR SDRAM (double data rate synchronous dynamic random-access memory) to store the instructions and data of active applications. This version will also feature SATA-II and Gigabit Ethernet interfaces. Furthermore, there will also be general-purpose, multi-gigabit interfaces. In addition, the system will have dozens of transceivers that can support LVDS (low-voltage differential signaling), RS-422, or SpaceWire. The SpaceCube Mini includes an I/O card that can be customized to meet the needs of each mission. This version of the SpaceCube will be designed so that multiple Minis can be networked together using SpaceWire, Ethernet, or even a custom protocol. Scalability can be provided by networking multiple SpaceCube Minis together. Rigid-Flex technology is being targeted for the construction of the SpaceCube Mini, which will make the extremely compact and low-weight design feasible. The SpaceCube Mini is designed to fit in the compact CubeSat form factor, thus allowing deployment in a new class of missions that the previous SpaceCube versions were not suited for. At the time of this reporting, engineering units should be available in the summer 2012

SpaceCube Version 1.5

SpaceCube 1.5 is a high-performance and low-power system in a compact form factor. It is a hybrid processing system consisting of CPU (central processing unit), FPGA (field-programmable gate array), and DSP (digital signal processor) processing elements. The primary processing engine is the Virtex- 5 FX100T FPGA, which has two embedded processors. The SpaceCube 1.5 System was a bridge to the SpaceCube 2.0 and SpaceCube 2.0 Mini processing systems. The SpaceCube 1.5 system was the primary avionics in the successful SMART (Small Rocket/Spacecraft Technology) Sounding Rocket mission that was launched in the summer of 2011. For SMART and similar missions, an avionics processor is required that is reconfigurable, has high processing capability, has multi-gigabit interfaces, is low power, and comes in a rugged/compact form factor. The original SpaceCube 1.0 met a number of the criteria, but did not possess the multi-gigabit interfaces that were required and is a higher-cost system. The SpaceCube 1.5 was designed with those mission requirements in mind. The SpaceCube 1.5 features one Xilinx Virtex-5 FX100T FPGA and has excellent size, weight, and power characteristics [443 in. (approx. = 10108 cm), 3 lb (approx. = 1.4 kg), and 5 to 15 W depending on the application]. The estimated computing power of the two PowerPC 440s in the Virtex-5 FPGA is 1100 DMIPS each. The SpaceCube 1.5 includes two Gigabit Ethernet (1 Gbps) interfaces as well as two SATA-I/II interfaces (1.5 to 3.0 Gbps) for recording to data drives. The SpaceCube 1.5 also features DDR2 SDRAM (double data rate synchronous dynamic random access memory); 4- Gbit Flash for storing application code for the CPU, FPGA, and DSP processing elements; and a Xilinx Platform Flash XL to store FPGA configuration files or application code. The system also incorporates a 12 bit analog to digital converter with the ability to read 32 discrete analog sensor inputs. The SpaceCube 1.5 design also has a built-in accelerometer. In addition, the system has 12 receive and transmit RS- 422 interfaces for legacy support. The SpaceCube 1.5 processor card represents the first NASA Goddard design in a compact form factor featuring the Xilinx Virtex- 5. The SpaceCube 1.5 incorporates backward compatibility with the Space- Cube 1.0 form factor and stackable architecture. It also makes use of low-cost commercial parts, but is designed for operation in harsh environments

Spacecube V2.0 Micro Single Board Computer

A single board computer system radiation hardened for space flight includes a printed circuit board having a top side and bottom side; a reconfigurable field programmable gate array (FPGA) processor device disposed on the top side; a connector disposed on the top side; a plurality of peripheral components mounted on the bottom side; and wherein a size of the single board computer system is not greater than approximately 7 cm.times.7 cm

SpaceCube 2.0: An Advanced Hybrid Onboard Data Processor

The SpaceCube 2.0 is a compact, high performance, low-power onboard processing system that takes advantage of cutting-edge hybrid (CPU/FPGA/DSP) processing elements. The SpaceCube 2.0 design concept includes two commercial Virtex-5 field-programmable gate array (FPGA) parts protected by gradiation hardened by software" technology, and possesses exceptional size, weight, and power characteristics [5x5x7 in., 3.5 lb (approximately equal to 12.7 x 12.7 x 17.8 cm, 1.6 kg) 5-25 W, depending on the application fs required clock rate]. The two Virtex-5 FPGA parts are implemented in a unique back-toback configuration to maximize data transfer and computing performance. Draft computing power specifications for the SpaceCube 2.0 unit include four PowerPC 440s (1100 DMIPS each), 500+ DSP48Es (2x580 GMACS), 100+ LVDS high-speed serial I/Os (1.25 Gbps each), and 2x190 GFLOPS single-precision (65 GFLOPS double-precision) floating point performance. The SpaceCube 2.0 includes PROM memory for CPU boot, health and safety, and basic command and telemetry functionality; RAM memory for program execution; and FLASH/EEPROM memory to store algorithms and application code for the CPU, FPGA, and DSP processing elements. Program execution can be reconfigured in real time and algorithms can be updated, modified, and/or replaced at any point during the mission. Gigabit Ethernet, Spacewire, SATA and highspeed LVDS serial/parallel I/O channels are available for instrument/sensor data ingest, and mission-unique instrument interfaces can be accommodated using a compact PCI (cPCI) expansion card interface. The SpaceCube 2.0 can be utilized in NASA Earth Science, Helio/Astrophysics and Exploration missions, and Department of Defense satellites for onboard data processing. It can also be used in commercial communication and mapping satellites

The Copyright Pentalogy

The first comprehensive analysis of the July 2012 Supreme Court of Canada rulings on five copyright cases, this indispensible volume, edited by Michael Geist identifies the key aspects of the Court's decisions and considers the implications for the future of copyright law in Canada

Copyright Consultations Submission

In this submission, the author presents seven principal proposals for reform that he argues would foster innovation, creativity and marketplace success. First, he argues for an expanded fair dealing provision that would enhance its flexibility. His second reform proposal engages with the issue of anti-circumvention provisions, where he argues: 1) for a direct link between anti-circumvention provisions and copyright infringement; 2) against bans on devices that can be used to circumvent technological protection measures (provided that it has non-infringing uses); 3) for the creation of authorized circumventers; and 4) for a positive requirement to unlock for exceptions/right of access. The author then moves on to a consideration of intermediary provisions, and argues for the establishment of a legal safe harbor in the form of a ―notice and notice‖ takedown system for internet intermediaries and a useful provision for Information Location Tool Providers, while rejecting the ―three strikes‖ system adopted in other jurisdictions. Fourth, the author proposes reforming the backup copy provision and rationalizing the statutory damages provisions as a means of modernizing copyright law. The fifth reform proposal involves enhancing the public domain, by rejecting an extension in the copyright term and abolishing Crown copyright. Sixth, library provisions should rely on fair dealing provisions, while there should be no internet exception for education. Lastly, it should not be possible to contract out of the core protections and policies underlying the copyright balance