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9 results on '"Paglino, R."'

6. Dimensioning of an ATM switch with shared buffer and threshold priority

Author

Meyer, J.F., Montagna, S., and Paglino, R.

Subjects
Broadband transmission -- Analysis, Switching circuits -- Analysis, Business, Computers and office automation industries
Abstract

The performance of a shared-buffer switching element with a threshold priority mechanism is evaluated. The evaluation uses a discrete-time, finite-state Markov chain model of the switch with its source traffic and the steady state probabilities are approximated. Then, the loss probabilities are used to solve the dimensioning problem of the buffer capacity and threshold level such that each cell type has maximum cell loss probabilities.

Published
1993

7. Dimensioning of an ATM switch with shared buffer and threshold priority

Author

Department of Electrical Engineering and Computer Science, University of Michigan, Ann Arbor, MI, USA, Central Research Laboratories, Italtel, Milano, Italy, Meyer, John F., Montagna, S., Paglino, R., Department of Electrical Engineering and Computer Science, University of Michigan, Ann Arbor, MI, USA, Central Research Laboratories, Italtel, Milano, Italy, Meyer, John F., Montagna, S., and Paglino, R.

Abstract

A number of recent studies have addressed the use of priority mechanisms in Asynchronous Transfer Mode (ATM) switches. This investigation concerns the performance evaluation and dimensioning of a shared-buffer switching element with a threshold priority mechanism (partial buffer sharing). It assumes that incoming ATM cells are distinguished by a space priority assignment, i.e., loss of high priority cell should be less likely than loss of a low priority cell. The evaluation method is analytic, based on an approximate discrete-time, finite-state Markov model of a switch and its incoming traffic. The development focuse son the formulation of steady-state loss probabilities for each priority class. Evaluation of delay measures for each class is also supported by the model; results concerning the latter are illustrated without development. The analysis of loss probabilities is then used to dimension the buffer capacity and threshold level such that required maximum cell loss probabilities are just satisfied for each cell type. Moreover, when so dimensioned with respect to relatively stringent loss requirements, i.e., probabilities of 10-10 and 10-5 for high and low priority cells, respectively, we find that both loss performance and resource utilization are appreciably improved over a comparable switch without such a mechanism.

Published
2006

9. Biological treatment of Hydrothermal Liquefaction (HTL) wastewater: Analytical evaluation of continuous process streams

Author

Rosa Carbone, Ivano Vassura, Stefano Chiaberge, Martina Cavallo, Roberta Miglio, Paolina Pascalicchio, Alisar Kiwan, Daniele Fabbri, Cristian Torri, Roberto Paglino, Alessandro G. Rombolà, Torri C., Kiwan A., Cavallo M., Pascalicchio P., Fabbri D., Vassura I., Rombola A.G., Chiaberge S., Carbone R., Paglino R., and Miglio R.

Subjects
Waste to fuel, Chemistry, Process Chemistry and Technology, Chemical oxygen demand, Thermochemical-biological, Continuous stirred-tank reactor, 02 engineering and technology, Biodegradable waste, Hydrothermal treatment, 010501 environmental sciences, Pulp and paper industry, 01 natural sciences, Anaerobic digestion, Hydrothermal liquefaction, 020401 chemical engineering, Wastewater, 0204 chemical engineering, Safety, Risk, Reliability and Quality, Waste Management and Disposal, Effluent, Anaerobic exercise, Organic waste, 0105 earth and related environmental sciences, Biotechnology
Abstract

In order to deal with hydrothermal liquefaction wastewater (HTWW), a new anaerobic-aerobic continuous process was developed. The process, which included a sequence of Up-Flow Anaerobic Sludge Blanket (UASB) and downstream aerobic Continuously Stirred Tank Reactor (CSTR), was tested on the HTWW obtained from Waste to Fuel® demo plant developed by ENI s.p.a. [ 1 ]. Performance of the system was evaluated in term of methane yield and chemical oxygen demand (COD) abatement capability. Detailed fate of organic compounds was evaluated through different analytical techniques, highlighting main issues and potential of HTWW biological treatment. The system was fed with neat HTWW (189 gCOD L−1) for 2.5 y, with variable organic loading rate (OLR) and minimal external inputs. UASB reactors converted most of HTWW organics into volatile fatty acids (VFA) and methane with concurrent precipitation of oily like insoluble, whereas aerobic CSTR removed VFA from anaerobic effluent. Under regime conditions (ORL equal to 0.5 gCOD L−1 d−1) COD decreased from 189 to 6.6 gCOD L-1, showing 97 % COD abatement with the coupled anaerobic-aerobic treatment. Such a COD abatement was obtained by means of multiple effects, namely biomethanation, precipitation of organic matter and aerobic oxidation of fermentation products (VFA produced in anaerobic digestion) and subsequent aerobic oxidation (in downstream aerobic reactor). These effects accounted for 43, 40 and 17 % of the total COD decrease, respectively. Inhibition phenomena were the key challenge for improving methane yields and system productivities. The overall results confirmed that valorization of HTWW is a feasible task, albeit rather challenging.

Published
2021

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