Your search keyword '"Masaru Naruoka"' showing total 10 results

1. Wandering albatrosses exert high take-off effort only when both wind and waves are gentle

Author

Leo Uesaka, Yusuke Goto, Masaru Naruoka, Henri Weimerskirch, Katsufumi Sato, and Kentaro Q Sakamoto

Subjects

seabird, biologging, ocean environment, take-off, wandering albatross, Medicine, Science, Biology (General), QH301-705.5

Abstract

The relationship between the environment and marine animal small-scale behavior is not fully understood. This is largely due to the difficulty in obtaining environmental datasets with a high spatiotemporal precision. The problem is particularly pertinent in assessing the influence of environmental factors in rapid, high energy-consuming behavior such as seabird take-off. To fill the gaps in the existing environmental datasets, we employed novel techniques using animal-borne sensors with motion records to estimate wind and ocean wave parameters and evaluated their influence on wandering albatross take-off patterns. Measurements revealed that wind speed and wave heights experienced by wandering albatrosses during take-off ranged from 0.7 to 15.4 m/s and 1.6 to 6.4 m, respectively. The four indices measured (flapping number, frequency, sea surface running speed, and duration) also varied with the environmental conditions (e.g., flapping number varied from 0 to over 20). Importantly, take-off was easier under higher wave conditions than under lower wave conditions at a constant wind speed, and take-off effort increased only when both wind and waves were gentle. Our data suggest that both ocean waves and winds play important roles for albatross take-off and advances our current understanding of albatross flight mechanisms.

Published

2023

2. Animal-Borne Telemetry: An Integral Component of the Ocean Observing Toolkit

Author

Rob Harcourt, Ana M. M. Sequeira, Xuelei Zhang, Fabien Roquet, Kosei Komatsu, Michelle Heupel, Clive McMahon, Fred Whoriskey, Mark Meekan, Gemma Carroll, Stephanie Brodie, Colin Simpfendorfer, Mark Hindell, Ian Jonsen, Daniel P. Costa, Barbara Block, Mônica Muelbert, Bill Woodward, Mike Weise, Kim Aarestrup, Martin Biuw, Lars Boehme, Steven J. Bograd, Dorian Cazau, Jean-Benoit Charrassin, Steven J. Cooke, Paul Cowley, P. J. Nico de Bruyn, Tiphaine Jeanniard du Dot, Carlos Duarte, Víctor M. Eguíluz, Luciana C. Ferreira, Juan Fernández-Gracia, Kimberly Goetz, Yusuke Goto, Christophe Guinet, Mike Hammill, Graeme C. Hays, Elliott L. Hazen, Luis A. Hückstädt, Charlie Huveneers, Sara Iverson, Saifullah Arifin Jaaman, Kongkiat Kittiwattanawong, Kit M. Kovacs, Christian Lydersen, Tim Moltmann, Masaru Naruoka, Lachlan Phillips, Baptiste Picard, Nuno Queiroz, Gilles Reverdin, Katsufumi Sato, David W. Sims, Eva B. Thorstad, Michele Thums, Anne M. Treasure, Andrew W. Trites, Guy D. Williams, Yoshinari Yonehara, and Mike A. Fedak

Subjects

ocean observing, animal telemetry, animal movement, movement analysis, EOV, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

Animal telemetry is a powerful tool for observing marine animals and the physical environments that they inhabit, from coastal and continental shelf ecosystems to polar seas and open oceans. Satellite-linked biologgers and networks of acoustic receivers allow animals to be reliably monitored over scales of tens of meters to thousands of kilometers, giving insight into their habitat use, home range size, the phenology of migratory patterns and the biotic and abiotic factors that drive their distributions. Furthermore, physical environmental variables can be collected using animals as autonomous sampling platforms, increasing spatial and temporal coverage of global oceanographic observation systems. The use of animal telemetry, therefore, has the capacity to provide measures from a suite of essential ocean variables (EOVs) for improved monitoring of Earth's oceans. Here we outline the design features of animal telemetry systems, describe current applications and their benefits and challenges, and discuss future directions. We describe new analytical techniques that improve our ability to not only quantify animal movements but to also provide a powerful framework for comparative studies across taxa. We discuss the application of animal telemetry and its capacity to collect biotic and abiotic data, how the data collected can be incorporated into ocean observing systems, and the role these data can play in improved ocean management.

Published

2019

3. Albatrosses employ orientation and routing strategies similar to yacht racers.

Author

Yusuke Goto, Weimerskirch, Henri, Fukaya, Keiichi, Yoda, Ken, Masaru Naruoka, and Katsufumi Sato

Subjects

ALBATROSSES, YACHTS, TRAVEL time (Traffic engineering), YACHT racing, TRAVEL costs

Abstract

The way goal-oriented birds adjust their travel direction and route in response to wind significantly affects their travel costs. This is expected to be particularly pronounced in pelagic seabirds, which utilize a wind-dependent flight style called dynamic soaring. Dynamic soaring seabirds in situations without a definite goal, e.g. searching for prey, are known to preferentially fly with crosswinds or quartering-tailwinds to increase the speed and search area, and reduce travel costs. However, little is known about their reaction to wind when heading to a definite goal, such as homing. Homing tracks of wandering albatrosses (Diomedea exulans) vary from beelines to zigzags, which are similar to those of sailboats. Here, given that both albatrosses and sailboats travel slower in headwinds and tailwinds, we tested whether the time-minimizing strategies used by yacht racers can be compared to the locomotion patterns of wandering albatrosses. We predicted that when the goal is located upwind or downwind, albatrosses should deviate their travel directions from the goal on the mesoscale and increase the number of turns on the macroscale. Both hypotheses were supported by track data from albatrosses and racing yachts in the Southern Ocean confirming that albatrosses qualitatively employ the same strategy as yacht racers. Nevertheless, albatrosses did not strictly minimize their travel time, likely making their flight robust against wind fluctuations to reduce flight costs. Our study provides empirical evidence of tacking in albatrosses and demonstrates that man-made movement strategies provide a new perspective on the laws underlying wildlife movement. [ABSTRACT FROM AUTHOR]

Published

2024

4. Identification of Decentralized System with Common Parameters.

Author

Mizuho Takeuchi, Takahiro Kawaguchi, Masaki Inoue, Masaru Naruoka, and Shuichi Adachi

Published

2018

5. Estimation of Aerodynamic Coefficients of Flight Data and Factor Analysis of Uncertainty

Author

Tetsujiro Ninomiya, Masaru Naruoka, Takahiro Uchiyama, Kento Yamada, Makoto Ueno, and Hideyuki Sawada

Published

2023

6. Wandering albatross exert high take-off effort in weak wind with low wave conditions

Author

Leo Uesaka, Yusuke Goto, Masaru Naruoka, Henri Weimerskirch, Katsufumi Sato, and Kentaro Q. Sakamoto

Abstract

The relationship between the environment and the small-scaled behavior of marine animals is not fully understood. This is largely due to the difficulty in obtaining environmental datasets with a high spatiotemporal precision. The problem is particularly pertinent in assessing the influence of environmental factors in rapid high energy consuming behavior such as seabirds take-off. Here, to fill the gaps in existing database, we employed novel techniques using animal-borne sensors with motion records to estimate parameters on wind and ocean waves, and evaluated their influence on wandering albatrosses take-off. The measurement revealed that the wind speed and the wave height that the wandering albatrosses experienced during take-off ranged from 0.7 ∼ 15.4 m/s and 1.6 ∼ 6.4 m, respectively. The four indices that were measured (flapping number, frequency, running speed, and duration on the sea surface) also varied with the environmental conditions (i.e., flapping number varied from 0 to over 20). Importantly, taking-off was easier under higher wave condition in the constant wind speed, and take-off effort increased only when both wind and waves were gentle. Our data suggests that both ocean waves and winds play important roles in albatross take-off, and advances our current understanding of albatross flight mechanisms.Impact statementWinds and ocean waves condition experienced by albatrosses were estimated using animal-borne recorder and revealed that taking-off was easier under higher wave condition in the constant wind speed.

Published

2023

7. Weight Estimation of Aircraft in Flight by Sensor Fusion with Revised Forward-backward Smoother

Author

Atsuya Ishikawa, Masaru Naruoka, Tetsujiro Ninomiya, and Shuichi Adachi

Published

2022

8. Albatrosses employ orientation and routing strategies similar to yacht racers

Author

Yusuke Goto, Henri Weimerskirch, Keiichi Fukaya, Ken Yoda, Masaru Naruoka, and Katsufumi Sato

Abstract

The way goal-oriented birds adjust their travel direction and route in response to the wind significantly affects their travel costs. This is expected to be particularly pronounced in albatrosses, which employ a wind-dependent flight style called dynamic soaring. Dynamic soaring birds in situations without a definite goal, e.g. searching for prey, are known to preferentially fly with tail-to-side winds to increase the speed and search area. However, little is known about their reaction to wind when heading to a definite goal, such as returning to their nest. For example, returning tracks of albatrosses vary from beelines to zigzags similar to that of sailboats; however, there is no empirical test of whether the wind causes this variation. Here, based on the similar wind-dependent speed between albatrosses and sailboats, we tested whether the time-minimizing strategies used by yacht racers can explain the locomotion patterns of wandering albatrosses. We predicted that when the goal is located upwind or downwind, albatrosses should (i) deviate their travel directions from the goal on the microscale and (ii) increase the number of turns on the macroscale. Both hypotheses were supported by track data from albatrosses and racing yachts in the Southern Ocean confirming that albatrosses qualitatively employ the same strategy as yacht racers. Nevertheless, albatrosses did not strictly minimize their travel time, likely making their flight robust against wind fluctuations. Our study provides the first empirical evidence of tacking in albatrosses and demonstrates that man-made movement strategies provide a new perspective on the laws underlying wildlife movement.

Published

2022

9. Seabird Biologging System with Compact Waterproof Airflow Sensor

Author

Masaru Naruoka, Katsufumi Sato, Hidetoshi Takahashi, and Yoshinobu Inada

Subjects

010302 applied physics, seabird, General Computer Science, biology, airflow sensor, Airflow, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, wind tunnel experiment, biologging, biology.animal, 0103 physical sciences, Environmental science, Electrical and Electronic Engineering, Seabird, 0210 nano-technology, Marine engineering

Abstract

形態: カラー図版あり, Physical characteristics: Original contains color illustrations, Accepted: 2021-03-10, 資料番号: PA2120030000

Published

2021

10. Identification of Decentralized System with Common Parameters

Author

Masaki Inoue, Shuichi Adachi, Mizuho Takeuchi, Takahiro Kawaguchi, and Masaru Naruoka

Subjects

Identification (information), Mathematical optimization, Adaptive control, Data collection, Computer simulation, Computer science, Covariance matrix, Multi-agent system, Estimator, Decentralised system

Abstract

This paper addresses a system identification problem for multiple isolated systems whose parameters are partially identical. An approach to the problem is a centralized identification; a single estimator collects all the input-output data from all of the systems to estimate their parameters at once. However, the approach can be practically infeasible when it is applied to a large number of systems due to the limitation of computational and communication resources. To solve the issue, we propose a method of a networked identification composed of two stages: 1) Multiple estimators collect the data from their own target systems to independently derive temporary estimates of their parameters and a covariance matrix of the estimates. 2) Then, with communicating the temporary estimates and the covariance matrix, they update their estimates. We also show the optimality of the proposed networked identification method with respect to the modeling accuracy, which is equivalently achieved by the centralized identification. Finally, we show the effectiveness of the proposed method in a numerical simulation.

Published

2018