Dynamic Power Management of High Performance Network on Chip

With increased density of modern System on Chip(SoC) communication between nodes has become a major problem. Network on Chip is a novel on chip communication paradigm to solve this by using highly scalable and efficient packet switched network. The addition of intelligent networking on the chip adds to the chip’s power consumption thus making management of communication power an interesting and challenging research problem. While VLSI techniques have evolved over time to enable power reduction in the circuit level, the highly dynamic nature of modern large SoC demand more than that. This dissertation explores some innovative dynamic solutions to manage the ever increasing communication power in the post sub-micron era. Today’s highly integrated SoCs require great level of cross layer optimizations to provide maximum efficiency. This dissertation aims at the dynamic power management problem from top. Starting with a system level distribution and management down to microarchitecture enhancements were found necessary to deliver maximum power efficiency. A distributed power budget sharing technique is proposed. To efficiently satisfy the established power budget, a novel flow control and throttling technique is proposed. Finally power efficiency of underlying microarchitecture is explored and novel buffer and link management techniques are developed. All of the proposed techniques yield improvement in power-performance efficiency of the NoC infrastructure

Amulet string contact leukoderma and its differentiation from vitiligo

A young adult factory worker presented with a linear depigmented vitiliginous patch on his right arm at the site where a silver amulet had been fixed with a nylon thread. He claimed that it was occupational in origin and demanded compensation, but patch testing with the nylon thread of the amulet and its extracted dyes proved that the contact leukoderma was due to the thread

Facet-Dependent Photodegradation of Methylene Blue Using Pristine CeO2 Nanostructures

This work comprises the shape-and facet-dependent catalytic efficacies of different morphologies of CeO2, namely, hexagonal, rectangular, and square. The formation of different shapes of CeO2 is controlled using polyvinyl pyrrolidone as a surfactant. The surface reactivity of formation of differently exposed CeO2 facets is thoroughly investigated using UV-visible, photoluminescence, Raman, and X-ray photoelectron spectroscopies. A correlation between the growth of a surface-reactive facet and the corresponding oxygen vacancies is also established. Considering the tremendous contamination, caused by the textile effluents, the present study articulates the facet-dependent photocatalytic activities of pristine CeO2 for complete degradation of methylene blue within 175 min. The observed degradation time deploying pristine CeO2 as a catalyst is the shortest to be reported in the literature to our best knowledge

Tuning of Electrical, Magnetic, and Topological Properties of Magnetic Weyl Semimetal Mn3+x_{3+x}Ge by Fe doping

We report on the tuning of electrical, magnetic, and topological properties of the magnetic Weyl semimetal (Mn$_{3+x}$Ge) by Fe doping at the Mn site, Mn$_{(3+x)-\delta}$Fe$_{\delta}$Ge ($\delta$=0, 0.30, and 0.62). Fe doping significantly changes the electrical and magnetic properties of Mn$_{3+x}$Ge. The resistivity of the parent compound displays metallic behavior, the system with $\delta$=0.30 of Fe doping exhibits semiconducting or bad-metallic behavior, and the system with $\delta$=0.62 of Fe doping demonstrates a metal-insulator transition at around 100 K. Further, we observe that the Fe doping increases in-plane ferromagnetism, magnetocrystalline anisotropy, and induces a spin-glass state at low temperatures. Surprisingly, topological Hall state has been noticed at a Fe doping of $\delta$=0.30 that is not found in the parent compound or with $\delta$=0.62 of Fe doping. In addition, spontaneous anomalous Hall effect observed in the parent system is significantly reduced with increasing Fe doping concentration.Comment: 16 pages and 5 figures, accepted in Journal of Physics: Condensed Matte

Seasonal dynamics of Shatavarin-IV, a potential biomarker of Asparagus racemosus by HPTLC: Possible validation of the ancient Ayurvedic text.

174-181The medicinal property of Asparagus racemosus is primarily attributed to its constituent steroidal saponins, particularly the major component, shatavarin-IV. Thus, it can serve as a biomarker and its level can decide of the utility of the plant cultivar as a drug. Hence, a sensitive, reliable and quantitative High Performance Thin Layer Chromatography (HPTLC) method has been established for quantification of shatavarin-IV in the methanolic extracts of the roots collected in both summer and rainy seasons. The extracts of the powders of dried roots were applied to silica gel 60 F254 aluminum-supported precoated TLC plates and developed with n-hexane: ethyl acetate: methanol, 80:10:10 (v/v), as the mobile phase. Shatavarin-IV was detected and quantified by densitometry at λ = 336 nm. The accuracy of the method was checked by conducting recovery studies at three different levels of shatavarin-IV. The average recovery was found to be 101% and 107% for summer and rainy seasons respectively. The shatavarin-IV contents, as estimated by the proposed method were 12.5 μg gm-1 and 10.9 μg gm-1 in summer and rainy roots respectively. The entire method was performed six times (n=6) to check the repeatability. The proposed HPTLC method for quantitative monitoring of shatavarin-IV in A. racemosus roots collected in different seasons strictly adhered to the validation issues laid down by the ICH guidelines. The method is reliable reproducible and highly precise and selective

Seasonal dynamics of Shatavarin-IV, a potential biomarker of Asparagus racemosus by HPTLC: Possible validation of the ancient Ayurvedic text.

The medicinal property of Asparagus racemosus is primarily attributed to its constituent steroidal saponins, particularly the major component, shatavarin-IV. Thus, it can serve as a biomarker and its level can decide of the utility of the plant cultivar as a drug. Hence, a sensitive, reliable and quantitative High Performance Thin Layer Chromatography (HPTLC) method has been established for quantification of shatavarin-IV in the methanolic extracts of the roots collected in both summer and rainy seasons. The extracts of the powders of dried roots were applied to silica gel 60 F254 aluminum-supported precoated TLC plates and developed with n-hexane: ethyl acetate: methanol, 80:10:10 (v/v), as the mobile phase. Shatavarin-IV was detected and quantified by densitometry at λ = 336 nm. The accuracy of the method was checked by conducting recovery studies at three different levels of shatavarin-IV. The average recovery was found to be 101% and 107% for summer and rainy seasons respectively. The shatavarin-IV contents, as estimated by the proposed method were 12.5 μg gm-1 and 10.9 μg gm-1 in summer and rainy roots respectively. The entire method was performed six times (n=6) to check the repeatability. The proposed HPTLC method for quantitative monitoring of shatavarin-IV in A. racemosus roots collected in different seasons strictly adhered to the validation issues laid down by the ICH guidelines. The method is reliable reproducible and highly precise and selective

Prediction-based protein engineering of domain I of Cry2A entomocidal toxin of Bacillus thuringiensis for the enhancement of toxicity against lepidopteran insects

Issues relating to sustenance of the usefulness of genetically modified first generation Bt crop plants in the farmer’s field are of great concern for crop scientists. Additional biotechnological strategies need to be in place to safeguard the possibility for yield loss of Bt crop by other lepidopteran insects that are insensitive to the Cry1A toxin, and also against the possibility for emergence of resistant insects. In this respect, Cry2A toxin has figured as a prospective candidate to be the second toxin to offer the required protection along with Cry1A. In the present study, the entomocidal potency of Cry2A toxin was enhanced through knowledge-based protein engineering of the toxin molecule. Deletion of 42 amino acid residues from the N-terminal end of the peptide followed by the replacement of Lys residues by nonpolar amino acids in the putative transmembrane region including the introduction of Pro resulted in a 4.1–6.6-fold increase in the toxicity of the peptide against three major lepidopteran insect pests of crop plants