Push-Pull Messaging: a high-performance communication mechanism for commodity SMP clusters

Push-Pull Messaging is a novel messaging mechanism for high-speed interprocess communication in a cluster of symmetric multi-processors (SMP) machines. This messaging mechanism exploits the parallelism in SMP nodes by allowing the execution of communication stages of a messaging event on different processors to achieve maximum performance. Push-Pull Messaging facilitates further improvement on communication performance by employing three optimizing techniques in our design: (1) Cross-Space Zero Buffer provides a unified buffer management mechanism to achieve a copy-less communication for the data transfer among processes within a SMP node. (2) Address Translation Overhead Masking removes the address translation overhead from the critical path in the internode communication. (3) Push-and-Acknowledge Overlapping overlaps the push and acknowledge phases to hide the acknowledge latency. Overall, Push-Pull Messaging effectively utilizes the system resources and improves the communication speed. It has been implemented to support high-speed communication for connecting quad Pentium Pro SMPs with 100 Mbit/s Fast Ethernet.published_or_final_versio

The moderating effect of social capital and environmental dynamism on the link between entrepreneurial orientation and resource acquisition

This study attempts to define the four constructs identified in the title and examine patterns of interaction among them. It begins by demonstrating that entrepreneurial orientation influences resource acquisition. It then puts forward a set of parameters to assess the degree to which two factors identified as social capital and environmental dynamism affect an entrepreneurial orientation resource acquisition equation. The study finds that there are relationships between all four of the constructs, but in three propositions developed in the course of discussion it puts forward issues that may be clarified by future research, which from various angles could show how entrepreneurially oriented firms react differently from more established firms in terms of their acquisition of resources and interaction with social capital and environmental dynamism. © 2011 Springer Science+Business Media B.V

Fiber-optic flow sensors for high-temperature environment operation up to 800°C

This Letter presents an all-optical high-temperature flow sensor based on hot-wire anemometry. High-attenuation fibers (HAFs) were used as the heating elements. High-temperature-stable regenerated fiber Bragg gratings were inscribed in HAFs and in standard telecom fibers as temperature sensors. Using in-fiber light as both the heating power source and the interrogation light source, regenerative fiber Bragg grating sensors were used to gauge the heat transfer from an optically powered heating element induced by the gas flow. Reliable gas flow measurements were demonstrated between 0.066 m/s and 0.66 m/s from the room temperature to 800°C. This Letter presents a compact, low-cost, and multiflexible approach to measure gas flow for high-temperature harsh environments. © 2014 Optical Society of America

Entrepreneurial Orientation and Organizational Learning on SMEs' Innovation

Entrepreneurial orientation (EO) is a driver of firms’ innovation. The phenomenon of EO as a prerequisite for innovation has become a central focus of corporate entrepreneurship literature. Despite an abundance of research suggesting that innovation capability contributes to SMEs’ performance, little is known how dimensions of EO specifically influence SMEs’ innovation. Furthermore, although prior research has examined various factors that influence the EO– innovation relationship, few studies have address views how organizational learning influences the EO-innovation relationship in the SMEs context. Based on the literature review, our study attempts to fill this gap by postulating that entrepreneurial innovativeness, proactiveness and risk-taking are related to SMEs’ innovation and that organizational learning positively moderates the EO–innovation relationships

Nonlinear lightwave circuits in chalcogenide glasses fabricated by ultrafast laser

This Letter reports a nonlinear directional waveguide coupler written by ultrafast laser in gallium lanthanum sulfide chalcogenide glass. The nonlinear waveguide device is tested with laser pulses input in two orthogonal polarizations, and all optical switching at 1040 nm between the two coupled waveguides is observed at a peak fluence of 16 GW?cm2. The spectra and autocorrelation measurement from the waveguide outputs show dominant nonlinear effects and negligible dispersion for light propagation in both channels. © 2014 Optical Society of America

Distributed flow sensing using optical hot-wire grid

An optical hot-wire flow sensing grid is presented using a single piece of self-heated optical fiber to perform distributed flow measurement. The flow-induced temperature loss profiles along the fiber are interrogated by the in-fiber Rayleigh backscattering, and spatially resolved in millimeter resolution using optical frequency domain reflectometry (OFDR). The flow rate, position, and flow direction are retrieved simultaneously. Both electrical and optical on-fiber heating were demonstrated to suit different flow sensing applications. © 2012 Optical Society of America

Nonlinear optical localization in embedded chalcogenide waveguide arrays

We report the nonlinear optical localization in an embedded waveguide array fabricated in chalcogenide glass. The array, which consists of seven waveguides with circularly symmetric cross sections, is realized by ultrafast laser writing. Light propagation in the chalcogenide waveguide array is studied with near infrared laser pulses centered at 1040 nm. The peak intensity required for nonlinear localization for the 1-cm long waveguide array was 35.1 GW/cm 2, using 10-nJ pulses with 300-fs pulse width, which is 70 times lower than that reported in fused silica waveguide arrays and with over 7 times shorter interaction distance. Results reported in this paper demonstrated that ultrafast laser writing is a viable tool to produce 3D all-optical switching waveguide circuits in chalcogenide glass. © 2014 Author(s)

All-fiber ultrafast thulium-doped fiber ring laser with dissipative soliton and noise-like output in normal dispersion by single-wall carbon nanotubes

An ultrafast thulium-doped fiber laser with large net normal dispersion has been developed to produce dissipative soliton and noise-like outputs at 1.9 μm. The mode-locked operation was enabled by using single-wall carbon nanotubes as saturable absorber for all-fiber configuration. Dissipative soliton in normal dispersion produced by the fiber laser oscillator was centered at 1947 nm with 4.1-nm FWHM bandwidth and 0.45 nJ/pulse. The output dissipative soliton pulses were compressed to 2.3 ps outside the laser cavity. © 2013 AIP Publishing LLC

All-fiber passively mode-locked thulium-doped fiber ring laser using optically deposited graphene saturable absorbers

An all-fiber passively mode-locked thulium-doped fiber ring oscillator is constructed using optically deposited few layer graphene micro-sheets as the saturable absorber (SA). The mode-lock operation was achieved by 130-mW pump power at 1.5-μm. The fiber oscillator produces 2.1-ps soliton pulse output with 80-pJ per pulse energy. The 3-dB bandwidth of the laser output was measured as 2.2-nm. The RF signal-to-noise ratio of 50-dB and sub 20-Hz 3-dB bandwidth of the laser output confirms the stable laser operation with low time jittering. This paper shows that graphene can be an effective saturable absorber for the development of mid-IR fiber mode-locked laser. © 2013 American Institute of Physics

Distributed liquid level sensors using self-heated optical fibers for cryogenic liquid management

We present a continuous liquid level sensing system for both room temperature and cryogenic fluids with millimeter spatial resolution. Change of in-fiber Rayleigh backscattering signal from the distinct thermal response of the heated sensing fiber in liquid and in air were interrogated and spatially resolved using the optical frequency domain reflectometry. Both electrical and optical heating techniques were investigated for cryogenic liquid applications at 4 K, 77 K, and the room temperature. The successful combination of self-heated fiber and wavelength-swept Rayleigh scattering interferometry provides, for the first time to our best knowledge, a truly distributed fuel gauge with high spatial resolution for cryogenic fuel storage, transportation, and management on ground and in space. © 2012 Optical Society of America