Your search keyword '"Garde, Baptiste"' showing total 15 results

1. Fine-scale changes in flight effort revealed by animal-borne loggers

Author

Garde, Baptiste, Shepard, Emily, Wilson, Rory, Portugal, Steve, and Borger, Luca

Abstract

The movements of the air are central to the life of flying birds, because they can determine whether the costs of flight are closer to resting or sprinting, and whether birds are able to reach their destination. Yet for species relying mainly on flapping flight, studies about the effects of weather on flight effort have mainly focussed on wind, with other atmospheric factors receiving less attention. In addition, with the development of new technologies to measure flight effort, it has become clear that some methods need standardisation and further verification. The goal of this PhD is to provide insight into how atmospheric conditions affect flight costs more broadly and study the extent to which birds prioritise energy expenditure over other currencies, such as time and risk. I used high-frequency data-loggers to explore the combined effects of wind and thermals, as well as air density, on flight effort over fine scales, as well as how birds adjust their behaviour to these factors. Results showed that pigeons (Columba livia), which are not limited by energy expenditure, prioritise speed over energy savings, and use a very costly flight style which could serve as a predator-avoidance strategy. I also found that wind support was a strong predictor of whether chick-rearing tropicbirds (Phaethon rubricauda) use thermal soaring to save energy during foraging trips, suggesting that birds were weighing up the trade-off between energy and time, and chose to save energy only when this would not cost them too much time. Comparison of air density between seasons also revealed that the flapping flight of tropicbirds was more costly during summer, when air density was lower. This finding shows that the effect of seasonal changes in air density on flight costs is significant, outweighing the influence of both wind and thermal availability. It also sheds new light on how flight costs (particularly those in tropical birds) might be affected by global change. Finally, the analysis of the accelerometer data showed that the type of tag used, as well as differences in the longitudinal position and attachment method, affected the amplitude of the signal, which has implications for the robustness of acceleration-based proxies for flight effort. Nonetheless, the adoption of standardized calibrations should facilitate the comparison of these metrics between study sites and through time, improving the prospect that they can be used to study the effect of a changing climate on flight costs and avian ecology.

Published

2022

2. How often should dead-reckoned animal movement paths be corrected for drift?

Author

Gunner, Richard M., Holton, Mark D., Scantlebury, David M., Hopkins, Phil, Shepard, Emily L. C., Fell, Adam J., Garde, Baptiste, Quintana, Flavio, Gómez-Laich, Agustina, Yoda, Ken, Yamamoto, Takashi, English, Holly, Ferreira, Sam, Govender, Danny, Viljoen, Pauli, Bruns, Angela, van Schalkwyk, O. Louis, Cole, Nik C., Tatayah, Vikash, Börger, Luca, Redcliffe, James, Bell, Stephen H., Marks, Nikki J., Bennett, Nigel C., Tonini, Mariano H., Williams, Hannah J., Duarte, Carlos M., van Rooyen, Martin C., Bertelsen, Mads F., Tambling, Craig J., and Wilson, Rory P.

Published

2021

3. Changing Air Density Affects Flight Costs in Low-Flying Birds

Author

Shepard, Emily, primary, Garde, Baptiste, additional, Krishnan, Krishnamoorthy, additional, Fell, Adam, additional, Tatayah, Vikash, additional, Jones, Carl G., additional, Cole, Nik C., additional, and Lempidakis, Emmanouil, additional

Published

2023

4. Estimating fine-scale changes in turbulence using the movements of a flapping flier

Author

Lempidakis, Emmanouil, primary, Ross, Andrew N., additional, Quetting, Michael, additional, Garde, Baptiste, additional, Wikelski, Martin, additional, and Shepard, Emily L. C., additional

Published

2022

5. The role of wingbeat frequency and amplitude in flight power

Author

Krishnan, Krishnamoorthy, primary, Garde, Baptiste, additional, Bennison, Ashley, additional, Cole, Nik C., additional, Cole, Emma-L., additional, Darby, Jamie, additional, Elliott, Kyle H., additional, Fell, Adam, additional, Gómez-Laich, Agustina, additional, de Grissac, Sophie, additional, Jessopp, Mark, additional, Lempidakis, Emmanouil, additional, Mizutani, Yuichi, additional, Prudor, Aurélien, additional, Quetting, Michael, additional, Quintana, Flavio, additional, Robotka, Hermina, additional, Roulin, Alexandre, additional, Ryan, Peter G., additional, Schalcher, Kim, additional, Schoombie, Stefan, additional, Tatayah, Vikash, additional, Tremblay, Fred, additional, Weimerskirch, Henri, additional, Whelan, Shannon, additional, Wikelski, Martin, additional, Yoda, Ken, additional, Hedenström, Anders, additional, and Shepard, Emily L. C., additional

Published

2022

6. The role of wingbeat frequency and amplitude in flight power

Author

Krishnan, Krishnamoorthy, Garde, Baptiste, Bennison, Ashley, Cole, Nik C., Cole, Emma-L., Darby, Jamie, Elliott, Kyle H., Fell, Adam, Gómez-Laich, Agustina, de Grissac, Sophie, Jessopp, Mark, Lempidakis, Emmanouil, Mizutani, Yuichi, Prudor, Aurélien, Quetting, Michael, Quintana, Flavio, Robotka, Hermina, Roulin, Alexandre, Ryan, Peter G., Schalcher, Kim, Schoombie, Stefan, Tatayah, Vikash, Tremblay, Fred, Weimerskirch, Henri, Whelan, Shannon, Wikelski, Martin, Yoda, Ken, Hedenström, Anders, Shepard, Emily L. C., Krishnan, Krishnamoorthy, Garde, Baptiste, Bennison, Ashley, Cole, Nik C., Cole, Emma-L., Darby, Jamie, Elliott, Kyle H., Fell, Adam, Gómez-Laich, Agustina, de Grissac, Sophie, Jessopp, Mark, Lempidakis, Emmanouil, Mizutani, Yuichi, Prudor, Aurélien, Quetting, Michael, Quintana, Flavio, Robotka, Hermina, Roulin, Alexandre, Ryan, Peter G., Schalcher, Kim, Schoombie, Stefan, Tatayah, Vikash, Tremblay, Fred, Weimerskirch, Henri, Whelan, Shannon, Wikelski, Martin, Yoda, Ken, Hedenström, Anders, and Shepard, Emily L. C.

Abstract

Body-mounted accelerometers provide a new prospect for estimating power use in flying birds, as the signal varies with the two major kinematic determinants of aerodynamic power: wingbeat frequency and amplitude. Yet wingbeat frequency is sometimes used as a proxy for power output in isolation. There is, therefore, a need to understand which kinematic parameter birds vary and whether this is predicted by flight mode (e.g. accelerating, ascending/descending flight), speed or morphology. We investigate this using high-frequency acceleration data from (i) 14 species flying in the wild, (ii) two species flying in controlled conditions in a wind tunnel and (iii) a review of experimental and field studies. While wingbeat frequency and amplitude were positively correlated, R2 values were generally low, supporting the idea that parameters can vary independently. Indeed, birds were more likely to modulate wingbeat amplitude for more energy-demanding flight modes, including climbing and take-off. Nonetheless, the striking variability, even within species and flight types, highlights the complexity of describing the kinematic relationships, which appear sensitive to both the biological and physical context. Notwithstanding this, acceleration metrics that incorporate both kinematic parameters should be more robust proxies for power than wingbeat frequency alone.

Published

2022

7. Supplemental information - Estimating fine-scale changes in turbulence using the movements of a flapping flier

Author

Lempidakis, Emmanouil, Ross, Andrew N., Quetting, Michael, Garde, Baptiste, Wikelski, Martin, and Shepard, Emily L. C.

Abstract

This includes supplementary figures and tables cited in the main manuscript, and the description of the procedure followed for estimating convective and shear velocities

Published

2022

8. The role of wingbeat frequency and amplitude in flight power: supplementary information

Author

Krishnan, Krishnamoorthy, Garde, Baptiste, Bennison, Ashley, Cole, Nik C., Cole, Emma-L., Darby, Jamie, Elliott, Kyle H., Fell, Adam, Gómez-Laich, Agustina, de Grissac, Sophie, Jessopp, Mark, Lempidakis, Emmanouil, Mizutani, Yuichi, Prudor, Aurélien, Quetting, Michael, Quintana, Flavio, Robotka, Hermina, Roulin, Alexandre, Ryan, Peter G., Schalcher, Kim, Schoombie, Stefan, Tatayah, Vikash, Tremblay, Fred, Weimerskirch, Henri, Whelan, Shannon, Wikelski, Martin, Yoda, Ken, Hedenström, Anders, and Shepard, Emily L. C.

Abstract

This file contains information on ethical approvals for the tagged birds, mixed model results of interaction between wingbeat amplitude, frequency and airspeed for tropic birds and the effect of sampling frequency on the estimation of acceleration signal amplitude for the manuscript "The role of wingbeat frequency and amplitude in flight power" published in the Journal of Royal Society Interface.

Published

2022

9. Ecological inference using data from accelerometers needs careful protocols

Author

Garde, Baptiste, primary, Wilson, Rory P., additional, Fell, Adam, additional, Cole, Nik, additional, Tatayah, Vikash, additional, Holton, Mark D., additional, Rose, Kayleigh A. R., additional, Metcalfe, Richard S., additional, Robotka, Hermina, additional, Wikelski, Martin, additional, Tremblay, Fred, additional, Whelan, Shannon, additional, Elliott, Kyle H., additional, and Shepard, Emily L. C., additional

Published

2022

10. Ecological inference using data from accelerometers needs careful protocols

Author

Garde, Baptiste, primary, Wilson, Rory P., additional, Fell, Adam, additional, Cole, Nik, additional, Tatayah, Vikash, additional, Holton, Mark D., additional, Rose, Kayleigh A. R., additional, Metcalfe, Richard S., additional, Robotka, Hermina, additional, Wikelski, Martin, additional, Tremblay, Fred, additional, Whelan, Shannon, additional, Elliott, Kyle H., additional, and Shepard, Emily L. C., additional

Published

2021

11. How Often Should Dead-Reckoned Animal Movement Paths be Corrected for Drift?

Author

gunner, Richard Michael, primary, Holton, Mark D, additional, Scantlebury, Mike D, additional, Hopkins, Phil, additional, Shepard, Emily LC, additional, Fell, Adam J, additional, Garde, Baptiste, additional, Quintana, Flavio, additional, Gómez-Laich, Agustina, additional, Yoda, Ken, additional, Yamamoto, Takashi, additional, English, Holly, additional, Ferreira, Sam, additional, Govender, Danny, additional, Viljoen, Pauli, additional, Bruns, Angela, additional, Schalkwyk, O. Louis van, additional, Cole, Nik C, additional, Tatayah, Vikash, additional, Börger, Luca, additional, Redcliffe, James, additional, Bell, Stephen H, additional, Marks, Nikki J, additional, Bennett, Nigel C, additional, Tonini, Mariano H, additional, Williams, Hannah J, additional, Duarte, Carlos M, additional, Rooyen, Martin C van, additional, Bertelsen, Mads F, additional, Tambling, Craig J, additional, and Wilson, Rory P, additional

Published

2021

12. Additional file 1 of How often should dead-reckoned animal movement paths be corrected for drift?

Author

Gunner, Richard M., Holton, Mark D., Scantlebury, David M., Hopkins, Phil, Shepard, Emily L. C., Fell, Adam J., Garde, Baptiste, Quintana, Flavio, Gómez-Laich, Agustina, Yoda, Ken, Yamamoto, Takashi, English, Holly, Ferreira, Sam, Govender, Danny, Viljoen, Pauli, Bruns, Angela, van Schalkwyk, O. Louis, Cole, Nik C., Tatayah, Vikash, Börger, Luca, Redcliffe, James, Bell, Stephen H., Marks, Nikki J., Bennett, Nigel C., Tonini, Mariano H., Williams, Hannah J., Duarte, Carlos M., van Rooyen, Martin C., Bertelsen, Mads F., Tambling, Craig J., and Wilson, Rory P.

Abstract

Additional file 1. Supplementary figures and dead-reckoning formulae.

Published

2021

13. Variability of speed and altitude of an ultralight from Fine-scale changes in speed and altitude suggest protean movements in homing pigeon flights

Author

Garde, Baptiste, Wilson, Rory P., Lempidakis, Emmanouil, Börger, Luca, Portugal, Steven J., Hedenström, Anders, Dell'Omo, Giacomo, Quetting, Michael, Wikelski, Martin, and Shepard, Emily L. C.

Abstract

Figure S1: Comparison of the rate of change of altitude and speed of an ultralight (A and C respectively) and a pigeon (B and D), flying at the same time, and with the same loggers. Violin plots show the distribution of the data during the flight; the upper and lower quartiles are represented by the upper and lower extremes of the box and the median by the thick black line.

Published

2021

14. Fine-scale changes in speed and altitude suggest protean movements in homing pigeon flights

Author

Garde, Baptiste, primary, Wilson, Rory P., additional, Lempidakis, Emmanouil, additional, Börger, Luca, additional, Portugal, Steven J., additional, Hedenström, Anders, additional, Dell'Omo, Giacomo, additional, Quetting, Michael, additional, Wikelski, Martin, additional, and Shepard, Emily L. C., additional

Published

2021

15. Turbulence causes kinematic and behavioural adjustments in a flapping flier

Author

Lempidakis, Emmanouil, Ross, Andrew N., Quetting, Michael, Krishnan, Krishnamoorthy, Garde, Baptiste, Wikelski, Martin, and Shepard, Emily L. C.

Abstract

Turbulence is a widespread phenomenon in the natural world, but its influence on flapping fliers remains little studied. We assessed how freestream turbulence affected the kinematics, flight effort and track properties of homing pigeons (Columba livia), using the fine-scale variations in flight height as a proxy for turbulence levels. Birds showed a small increase in their wingbeat amplitude with increasing turbulence (similar to laboratory studies), but this was accompanied by a reduction in mean wingbeat frequency, such that their flapping wing speed remained the same. Mean kinematic responses to turbulence may therefore enable birds to increase their stability without a reduction in propulsive efficiency. Nonetheless, the most marked response to turbulence was an increase in the variability of wingbeat frequency and amplitude. These stroke-to-stroke changes in kinematics provide instantaneous compensation for turbulence. They will also increase flight costs. Yet pigeons only made small adjustments to their flight altitude, likely resulting in little change in exposure to strong convective turbulence. Responses to turbulence were therefore distinct from responses to wind, with the costs of high turbulence being levied through an increase in the variability of their kinematics and airspeed. This highlights the value of investigating the variability in flight parameters in free-living animals.

Published

2024