Capability-based Authentication and Access Control in Internet of Things

Internet of Things (IoT) foresees the interaction and communication between different physical entities, which are constrained devices in this physical world. The entities also communicate with the Internet to provide solution for different complex problems. It goes for empowering future advances and dreams like, smart apartment, building automation, intelligent city construction, and e-health service. Secure data transmission is of prime importance in these scenarios. Standard IP-based security arrangements don’t address this issue as they are not composed in view of the restrictions of obliged gadgets. Consequently, more lightweight security components are required. The entities in the domain of IoT come from different vendors. Authentication and Authorization of these entities in a network demands the exchange of identity, certificates and protocol suites. High computation power and memory is required for this transmission. We propose a framework in which the authentication, authorization and key distribution is delegated. It also integrates capability-based fine-grained access control of services. Our evaluation implements different cryptographic algorithms to manage authentication and authorization of the entities in the domain of IoT using this framework. The simulation measures the time unit taken for managing these security aspects. The framework is also tested in a hardware-based testbed and justifies that this framework might be used in most of the IoT domain

Development of Process Flow Sheet for Recovering Strategic Mineral Monazite from a Lean-Grade Bramhagiri Coastal Placer Deposit, Odisha, India

The present investigation deals with the development of a process flow sheet for recovering strategic mineral monazite concentrate from a lean-grade offshore placer deposit of the Bramhagiri coast along the southeast coast of Odisha, India.In the present study, both dry and wet processes are investigated to improve the recovery and purity of monazite. The results of the pre-concentration studies reveal that by using multi-stage spiral concentrators, the Total Heavy Minerals [THM] have been upgraded to 97.8% with a monazite content of 0.33% from a feed sample containing 4.72% total heavy minerals and 0.01% monazite content. The beneficiation studies revealed that the feed was initially subjected to a high-tension separator, and the non-conducting fraction of the high-tension roll was further subjected to magnetic separation. The magnetic product was again subjected to a flotation process followed by cleaning of the flotation product using a magnetic separator. This magnetic product contains 98.89% monazite with 84% recovery and 0.28% yield from a spiral product containing 0.33% monazite and qualifies for extracting rare earths. It is worth recovering monazite mineral from even lean-grade deposits, as it is a source of uranium, thorium, and rare earth elements and is very high in demand for humankind due to technological advancements. In view of this, monazite recovery is not to be considered for the economic profitability of the process but for strategic requirements