Microvariability Detection of Mrk 421

The BL Lac object Mrk 421 was observed in optical bands from 2009 April to 2012 May with the 1.0 m telescope at Weihai Observatory of Shandong University. Microvariability was analysed by C and F tests, but no significant microvariability was detected during our observations.Comment: 2 pages, 1 figur

Optimization Of Operational Costs In Data Centers

The electricity cost of cloud computing data centers dominated by server power and cooling power is growing rapidly. To tackle this problem, inlet air with moderate temperature and server consolidation are widely adopted. However, the benefit of these two methods is limited due to conventional air cooling systems ineffectiveness caused by re-circulation and low heat capacity. To address this problem, hybrid air and liquid cooling, as a practical and inexpensive approach, has been introduced. In this work, we quantitatively analyze the impact of server consolidation and temperature of cooling water on the total electricity and server maintenance costs in hybrid cooling data centers. To minimize the total costs, we proposed to maintain sweet temperature and ASTT (available sleeping time threshold) by which a joint cost optimization can be satisfied. By using real world traces, the potential savings of sweet temperature and ASTT are estimated to be average 18% of the total cost while 99% requests are satisfied compared to a strategy which only reduces electricity cost. The co-optimization is extended to increase the benefit of the renewable energy and its profit grows as the more wind power is supplied

Increasing Off-Chip Bandwidth and Mitigating Dark Silicon via Switchable Pins

Off-chip memory bandwidth has been considered as one of the major limiting factors to processor performance, especially for multi-cores and many-cores. Conventional processor design allocates a large portion of off-chip pins to deliver power, leaving a small number of pins for processor signal communication. We observed that the processor requires much less power than that can be supplied during memory intensive stages in some cases. In this work, we propose a dynamic pin switch technique to alleviate the bandwidth limitation issue. The technique is introduced to dynamically exploit the surplus pins for power delivery in the memory intensive phases and uses them to provide extra bandwidth for the program executions, thus significantly boosting the performance. We also explore its performance benefit in the era of Phase-change memory (PCM) and prove that the technique can be applied beyond DRAM-based memory systems. On the other hand, the end of Dennard Scaling has led to a large amount of inactive or significantly under-clocked transistors on modern chip multi-processors in order to comply with the power budget and prevent the processors from overheating. This so-called “dark silicon” is one of the most critical constraints that will hinder the scaling with Moore’s Law in the future. While advanced cooling techniques, such as liquid cooling, can effectively decrease the chip temperature and alleviate the power constraints; the peak performance, determined by the maximum number of transistors which are allowed to switch simultaneously, is still confined by the amount of power pins on the chip package. In this paper, we propose a novel mechanism to power up the dark silicon by dynamically switching a portion of I/O pins to power pins when off-chip communications are less frequent. By enabling extra cores or increasing processor frequency, the proposed strategy can significantly boost performance compared with traditional designs. Using the switchable pins can increase inter-socket bandwidth as one of performance bottlenecks. Multi-socket computer systems are popular in workstations and servers. However, they suffer from the relatively low bandwidth of inter-socket communication especially for massive parallel workloads that generates many inter-socket requests for synchronizations and remote memory accesses. The inter-socket traffic poses a huge pressure on the underlying networks fully connecting all processors with the limited bandwidth that is confined by pin resources. Given the constraint, we propose to dynamically increase the inter-socket band-width, trading off with lower off-chip memory bandwidth when the systems have heavy inter-socket communication but few off-chip memory accesses. The design increases the physical bandwidth of inter-socket communication via switching the function of pins from off-chip memory accesses to inter-socket communication

The dichotomy of Nikodym sets and local smoothing estimates for wave equations

We show that Nikodym sets and local smoothing estimates for linear wave equations form a dichotomy: If Nikodym sets for a family of curves exist, then the related maximal operator is not bounded on $L^p(\mathbb{R}^2)$ for any $p<\infty$; if Nikodym sets do not exist, then local smoothing estimates hold, and the related maximal operator is bounded on $L^p(\mathbb{R}^2)$ for some $p<\infty$. Whenever the maximal operator is bounded on $L^p(\mathbb{R}^2)$ for some $p<\infty$, we also determine the sharp exponent for $L^p(\mathbb{R}^2)$ bounds

Ami-The Chemist's Amanuensis

Poster presented at the VSMF Symposium held at the Unilever Centre on 2011-01-17The Ami project was a six month Rapid Innovation project sponsored by JISC to explore the Virtual Research Environment space. The project brainstormed with chemists and decided to investigate ways to facilitate monitoring and collection of experimental data. A frequently encountered use-case was identified of how the chemist reaches the end of an experiment, but finds an unexpected result. The ability to replay events can significantly help make sense of how things progressed. The project therefore concentrated on collecting a variety of dimensions of ancillary data – data that would not normally be collected due to practicality constraints. There were three main areas of investigation: 1) Development of a monitoring tool using infrared and ultrasonic sensors; 2) Time-lapse motion video capture (for example, videoing 5 seconds in every 60); and 3) Activity-driven video monitoring of the fume cupboard environs. The Ami client application was developed to control these separate logging functions. The application builds up a timeline of the events in the experiment and around the fume cupboard. The videos and data logs can then be reviewed after the experiment in order to help the chemist determine the exact timings and conditions used. The project experimented with ways in which a Microsoft Kinect could be used in a laboratory setting. Investigations suggest that it would not be an ideal device for controlling a mouse, but it shows promise for usages such as manipulating virtual molecules.Ami was a six month project under the “JISC Rapid Innovation Grants 10/09” programme, Grants for the Virtual Research Environment - Rapid Innovation funding call. [http://www.jisc.ac.uk/fundingopportunities/funding_calls/2009/10/vreri.aspx

A multi-parameter cinematic curvature

We state a multi-parameter cinematic curvature condition, and prove $L^p$ bounds for related maximal operators

Boron Nitride Nanosheets Improve Sensitivity and Reusability of Surface Enhanced Raman Spectroscopy

Surface enhanced Raman spectroscopy (SERS) is a useful multidisciplinary analytic technique. However, it is still a challenge to produce SERS substrates that are highly sensitive, reproducible, stable, reusable, and scalable. Here, we demonstrate that atomically thin boron nitride (BN) nanosheets have many unique and desirable properties to help solve this challenge. The synergic effect of the atomic thickness, high flexibility, stronger surface adsorption capability, electrical insulation, impermeability, high thermal and chemical stability of BN nanosheets can increase the Raman sensitivity by up to two orders, and in the meantime attain long-term stability and extraordinary reusability not achievable by other materials. These advances will greatly facilitate the wider use of SERS in many fields