A Host Interface Architecture and Implementation for ATM Networks

The advent of high speed networks has increased demands on processor architectures. These architectural demands are due to the increase in network bandwidth relative to the speeds of processor components. One important component for a high-performance system is the workstation-to-network host interface . The solution presented in this thesis migrates a carefully selected set of protocol processing functions into hardware. The host interface is highly parallel and all per cell functions are performed by dedicated logic to maximize performance. There is a clean separation between the interface functions, such as segmentation and reassembly, and the interface/host communication. This architecture has been realized in a prototype which connects an IBM RISC System/6000 workstation to a SONET-based ATM network carrying data at the OC-3c1 rate of 155 Mbps

Operating Systems Support for End-to-End Gbps Networking

This paper argues that workstation host interfaces and operating systems are a crucial element in achieving end-to-end Gbps bandwidths for applications in distributed environments. We describe several host interface architectures, discuss the interaction between the interface and host operating system, and report on an ATM host interface built at the University of Pennsylvania. Concurrently designing a host interface and software support allows careful balancing of hardware and software functions. Key ideas include use of buffer management techniques to reduce copying and scheduling data transfers using clocked interrupts. Clocked interrupts also aid with bandwidth allocation. Our interface can deliver a sustained 130 Mbps bandwidth to applications, roughly OC-3c link speed. Ninety-three percent of the host hardware subsystem throughput is delivered to the application with a small measured impact on other applications processing

Experimental Evaluation of an ATM Host Interface

We have previously reported a design for a host interface board intended to connect workstations to ATM networks, and an implementation that was underway. Since then, we have made some modifications to the hardware implementation, and implemented software support. Our prototype connects an IBM RS/6000 to a SONET-based ATM network carrying data at the OC-3c rate of 155Mbps. In this paper, we discuss an experimental evaluation of the interface and supporting software. Our experiments uncovered an unexpected bottleneck in providing high bandwidth to application processes, and we suggest a number of possible improvements to workstation architectures to address this bottleneck

Implementation and Performance of An ATM Host Interface for Workstations

This brief paper outlines our strategies for providing a hardware and software solution to interfacing hosts to high-performance networks. Our prototype implementation connects an IBM RS/6000 to a SONET-based ATM network carrying data at the OC-3c rate of 155Mbps. We have measured application-to-network data rates of up to 130 Mbps

AVATAR -- ATM VideoAudio Transmit and Receive

To facilitate the transport of audio and video data across emerging Asynchronous Transfer Mode (ATM) networks, a simple, low cost, audio/video ATM appliance, the AVATAR, has been developed. This appliance is capable of handling uncompressed bidirectional audio and NTSC video connections. The intended applications for this device include TeleMentoring (a NSF sponsored exploration of distance mentoring), video conferencing, and network monitoring. Our experience has shown that AVATAR is an effective, low cost means of providing multimedia connectivity between sites within the Aurora Gigabit testbed

Here for more than just research: Postdoctoral training and transitions in STEM fields

The purpose of this research is to better understand how academic researchers in STEM fields identify and access postdoctoral positions, transition into postdoctoral roles, and access training, development opportunities, and networks once they are at their postdoctoral institution. Furthermore, this study aims to describe how aspects of identity influence any of these facets of postdoctoral training. There is relatively little research into the postdoctoral training stage. This qualitative, exploratory study is meant to describe how postdoctoral scholars view and understand their own experiences in the role, and how their identity may or may not impact this experience. Sixteen participants, most from backgrounds that are underrepresented in their disciplines, were recruited from research institutions across the country to participate in a 1-hour interview about their academic experiences, their postdoc experience, and their career goals. Findings include the importance of networks and support structures for understanding how to identify and transition into postdoctoral positions, the hidden curriculum related to the postdoctoral training experience, and the role of values and cultural identity in setting postdoc and career goals. These findings fill a gap in the literature by better representing current postdocs’ expectations for this training period, specifically as it relates to potential transitions into a faculty role. The results can be used to design postdoc training programs that emphasize equity in STEM fields

Leaf trichomes and foliar chemistry mediate defence against glasshouse thrips; Heliothrips haemorrhoidalis (Bouché) in Rhododendron simsii

Herbivore defence mechanisms are a costly diversion of resources away from growth and reproduction. Thus time-limited and tissue specific expression in critical plant parts is more efficient as defined by optimal defence theory. Surprisingly little is known about Rhododendron herbivore defence but it may be mediated by combined chemical and physical mechanisms. Rhododendron simsii Planch. survives cyclic infestations of a leaf-feeding thrips, Heliothrips haemorrhoidalis, which severely damage mature leaves but avoid terminal young leaves suggesting specific, localised defence expression. We examined correlations between the distribution of thrips and feeding damage with density of trichomes and the concentration of the diterpenoid, grayanotoxin I, a compound implicated in but not previously reported to meditate invertebrate defence in Rhododendron. Our data show that as leaves matured the number of thrips and area of feeding damage increased as trichome density and grayanotoxin I concentration decreased, this inverse correlation 10 suggesting trichomes and grayanotoxin I mediate defence in younger leaf tissue. Grayanotoxin I was tested against H. haemorrhoidalis and was toxic to immature life stages and repellent to the adult thrips, reducing numbers of first instars emerging on leaves when applied at ecologically relevant concentrations. This work demonstrates that the pattern of defensive traits in foliage of a species of Rhododendron is key to its ability to tolerate cyclic infestations of a generalist herbivore, effectively conserving vital tissues required for growth and reproduction

Event Signaling Within Higher Performance Network Systems

The afterburner ATM link Adapter has allowed us to evaluate three event-signaling schemes: polling, traditional interrupts and the clocked interrupts first investigated in our operating system work in AURORA. The schemes are evaluated in the context of a single-copy TCP/IP stack. The experimental results indicate that clocked interrupts can provide throughput comparable with traditional interrupts for dedicated machines (up to over 144 Mbps, the highest TCP/IP/ATM throughput reported), and better performance when the machines are loaded with an artificial workload. Polling, implemented to be used with an unmodified netperf measurement tool, was competitive for small TCP/IP socket buffer sizes (¡32KB). We concluded that clocked interrupts may be preferable for applications requiring high throughput on systems with heavy processing workloads, such as servers

Microbial Interactions in the Phyllosphere Increase Plant Performance Under Herbivore Biotic Stress

The phyllosphere supports a tremendous diversity of microbes and other organisms. However, little is known about the colonization and survival of pathogenic and beneficial bacteria alone or together in the phyllosphere across the whole plant life-cycle under herbivory, which hinders our ability to understand the role of phyllosphere bacteria on plant performance. We addressed these questions in experiments using four genetically and biogeographically diverse accessions of Arabidopsis thaliana, three ecologically important bacterial strains (Pseudomonas syringae DC3000, Xanthomonas campestris, both pathogens, and Bacillus cereus, plant beneficial) under common garden conditions that included fungus gnats (Bradysia spp.). Plants supported greater abundance of B. cereus over either pathogenic strain in the phyllosphere under such greenhouse conditions. However, the Arabidopsis accessions performed much better (i.e., early flowering, biomass, siliques, and seeds per plant) in the presence of pathogenic bacteria rather than in the presence of the plant beneficial B. cereus. As a group, the plants inoculated with any of the three bacteria (Pst DC3000, Xanthomonas, or Bacillus) all had a higher fitness than uninoculated controls under these conditions. These results suggest that the plants grown under the pressure of different natural enemies, such as pathogens and an herbivore together perform relatively better, probably because natural enemies induce host defense against each other. However, in general, a positive impact of Bacillus on plant performance under herbivory may be due to its plant-beneficial properties. In contrast, bacterial species in the mixture (all three together) performed poorer than as monocultures in their total abundance and host plant growth promotion, possibly due to negative interspecific interactions among the bacteria. However, bacterial species richness linearly promoted seed production in the host plants under these conditions, suggesting that natural enemies diversity may be beneficial from the host perspective. Collectively, these results highlight the importance of bacterial community composition on plant performance and bacterial abundance in the phyllosphere