Is Accounting a Miserable Job?

Popular culture portrays accounting as a miserable job. Accounting research evaluating the boring “beancounter stereotype” argues that it is wrong and costly because it reduces the appeal of accounting to high quality students and exacts a psychological toll on accountants who are thus stereotyped. In this study, we empirically test the basic question: is accounting a miserable job? We use data from a variety of sources that enable us to measure workplace misery and model it as a function of work tasks and personal characteristics of workers across occupations. We find that accounting work is particularly sedentary, rigid, repetitive, constrained, and rules-centric; characteristics that are consistent with the accounting stereotype and that prior work outside of accounting has shown are associated with workplace misery. However, we find that accounting is not a miserable job. In univariate and multivariate tests, we find that accounting has misery values that are either near the average or are better than average for comparison jobs. This apparent paradox could be a positive consequence of accounting stereotypes, which may facilitate the matching of potentially miserable work with people who are most prepared to tolerate it. Indeed, we present longitudinal evidence suggesting that accounting attracts people with personalities suited to repetitive and rules-centric work and who have psychosocial histories that make them robust to stress. Workplace misery is costly to workers, employers, and society and accounting stereotypes have value if they facilitate informed career selection

Effect of local chemistry and structure on thermal transport in doped GaAs

Using a first-principles approach, we analyze the impact of \textit{DX} centers formed by S, Se, and Te dopant atoms on the thermal conductivity of GaAs. Our results are in good agreement with experiments and unveil the physics behind the drastically different effect of each kind of defect. We establish a causal chain linking the electronic structure of the dopants to the thermal conductivity of the bulk solid, a macroscopic transport coefficient. Specifically, the presence of lone pairs leads to the formation of structurally asymmetric \textit{DX} centers that cause resonant scattering of incident phonons. The effect of such resonances is magnified when they affect the part of the spectrum most relevant for thermal transport. We show that these resonances are associated with localized vibrational modes in the perturbed phonon spectrum. Finally, we illustrate the connection between flat adjacent minima in the energy landscape and resonant phonon scattering through detailed analyses of the energy landscape of the defective structures.Comment: 7 pages, 7 figure

Task Migration for Fault-Tolerance in Mixed-Criticality Embedded Systems

In this paper we are interested in mixed-criticality embed-ded applications implemented on distributed architectures. Depending on their time-criticality, tasks can be hard or soft real-time and regarding safety-criticality, tasks can be fault-tolerant to transient faults, permanent faults, or have no dependability requirements. We use Earliest Deadline First (EDF) scheduling for the hard tasks and the Constant Bandwidth Server (CBS) for the soft tasks. The CBS pa-rameters determine the quality of service (QoS) of soft tasks. Transient faults are tolerated using checkpointing with roll-back recovery. For tolerating permanent faults in proces-sors, we use task migration, i.e., restarting the safety-critical tasks on other processors. We propose a Greedy-based on-line heuristic for the migration of safety-critical tasks, in response to permanent faults, and the adjustment of CBS parameters on the target processors, such that the faults are tolerated, the deadlines for the hard real-time tasks are sat-isfied and the QoS for soft tasks is maximized. The proposed online adaptive approach has been evaluated using several synthetic benchmarks and a real-life case study. 1

Synthesis of biochemical applications on digital microfluidic biochips with operation variability

Abstract—Microfluidic-based biochips are replacing the con-ventional biochemical analyzers, and are able to integrate on-chip all the necessary functions for biochemical analysis using microfluidics. The digital microfluidic biochips are based on the manipulation of liquids not as a continuous flow, but as discrete droplets. Researchers have presented approaches for the synthesis of digital microfluidic biochips, which, starting from a biochemical application and a given biochip architecture, determine the allocation, resource binding, scheduling and place-ment of the operations in the application. Existing approaches consider that on-chip operations, such as splitting a droplet of liquid, are perfect. However, these operations have variability margins, which can impact the correctness of the biochemical application. We consider that a split operation, which goes beyond specified variability bounds, is faulty. The fault is detected using on-chip volume sensors. We have proposed an abstract model for a biochemical application, consisting of a sequencing graph, which can capture all the fault scenarios in the application. Starting from this model, we have proposed a synthesis approach that, for a given chip area and number of sensors, can derive a fault-tolerant implementation. Two fault-tolerant scheduling techniques have been proposed and compared. We show that, by taking into account fault-occurrence information, we can derive better quality implementations, which leads to shorter application completion times, even in the case of faults. The proposed synthesis approach under operation variability has been evaluated using several benchmarks. I