P–P and Q–Q plots for assessing normality of residuals. by Kazuhiro Suzuki (160528)

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Characteristics of the participants. by Kazuhiro Suzuki (160528)

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Comparison of GHQ-12 total scores pre- and post- guideline change in the mask-wearing behavior. by Kazuhiro Suzuki (160528)

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Analysis sample data. by Kazuhiro Suzuki (160528)

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Multiple linear regression analysis for psychological distress (GHQ-12 scores). by Kazuhiro Suzuki (160528)

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Amplitude for A/L = 0.29. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Top view of the experimental setup. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Amplitude for A/L = 0.338. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Parameters of energy harvesting. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Graph for Max Amplitude/Length at G_y = 0. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Amplitude for A/L = 0.02. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Graph for maximum Frequency at G_y = 0. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Graph for maximum Power at G_y = 0. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Amplitude for A/L = 0.03. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Summary of experimentation results. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Piezoelectric eel. by Muhammad Hammad Bucha (21736111)

“…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”

Contains R code utilized in the analyses. by Arttu Autio-Kimura (20454681)

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Sex-based differences for combinations of brain regions and cell types, based on Mann-Whitney U-test. by Arttu Autio-Kimura (20454681)

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Bootstrapped spearman correlations from a randomly selected subset of male sample donor originating samples (n = 493). by Arttu Autio-Kimura (20454681)

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Spearman correlations between the age of the sample donor (20–70 years) and estimated proportions of neuronal, glial, and endothelial cells. by Arttu Autio-Kimura (20454681)

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