This clip shows a bat (not identified to species) flying near a turbine as imaged with a thermal camera. The recording shows the bat making numerous repeated passes behind the rotor swept area of a turbine. This activity is of particular interest to researchers because it provides a window into behavior that places bats at risk from turbine strikes.
Monitoring and Researching Bat Activity at Wind Turbines with Videography
The rapid expansion of wind energy nationwide is an important step toward reducing dependence on non-renewable sources of power. However, the magnitude of the wildlife impacts at wind energy facilities is a newly recognized threat, and the cumulative long-term impacts to various bat species are of increasing concern. It is estimated that more than 450,000 bat fatalities now occur each year at wind turbines in the U.S. and Canada (Cryan 2011).
Overview:
The rapid expansion of wind energy nationwide is an important step toward reducing dependence on non-renewable sources of power. However, the magnitude of the wildlife impacts at wind energy facilities is a newly recognized threat, and the cumulative long-term impacts to various bat species are of increasing concern. It is estimated that more than 450,000 bat fatalities now occur each year at wind turbines in the U.S. and Canada (Cryan 2011).
Assessing the risk industrial wind turbines pose to bats is hindered by low light conditions and the cryptic attributes of night-flying animals. With modern wind turbines now reaching as high as 150 m above the ground (equivalent to a 50-story building), there is presently no cost-effective standards for survey methods available for observing and measuring bat occurrence and behavior in the dark at heights and distances relevant to assessing wind-turbine risk. For example, radar and thermal imaging systems cannot always differentiate the types of animals being detected, and ground-based acoustic detectors can only sample up to about 40 meters, well below the turbine rotor-swept zone in which bats and birds are struck.
Monitoring high-flying nocturnal animals that occur intermittently requires sampling sessions of long duration. This need is often best met by deployment of remote technologies, particularly in situations that are unsafe for long-term occupancy by human observers (e.g., offshore environments and airstrips). A major challenge of such technological approaches is developing efficient ways to process and interpret the large amounts of data acquired. Video-based monitoring systems show great promise for monitoring flying nocturnal animals over entire nights and seasons. Motion analysis of digital imagery acquired by thermal infrared cameras has proven effective for quantifying night flights of bats emerging from caves, and thermal cameras have also been used to observe bat activity around turbines, but the techniques have not been combined as yet in an analytically tractable and cost-efficient system for long-term deployment. Our project is working toward producing standardized methods and tools that meet the challenges of successfully measuring bat activity and risks in association with wind turbines and in assessing and predicting bat mortality in conjunction with quantitative models based on improved surveys.
Project Objectives:
We propose to demonstrate a near infra-red (NIR) video system coupled with advanced digital processing and tracking algorithms to process target information for the purposes of assessing nocturnal animal occurrence and behavior. The system will include automated data processing to reduce the burden from imagery review. We will apply the NIR video system to a range of field settings, and validate the approach of detecting and tracking distant cryptic targets for use in monitoring of vertebrate populations. Specifically, we will demonstrate the application of very low-light cameras in combination with NIR illumination. Near-infrared illumination is a suitable lighting source because this wavelength range is not visible to vertebrates and will not affect behavior. Infrared cameras can also image through glass and other clear materials, whereas thermal IR cameras cannot and thus, the NIR system is better suited to weatherproof enclosures for long-term deployment (e.g., marine environments of offshore turbines).
This is the first field validation of NIR videography to nocturnally track and quantify target motion in mixed species settings at distances >100 m, and under realistic operational conditions and long-term deployment scenarios. The method will provide a cost-effective means to track animal activity, assess abundance and detect specific events of interest (e.g., fatality incidents at wind energy facilities; seabird disorientation and “fallout” at bright light sources; etc.). We expect the experimental and numerical endeavors of this work to quantify previously unexplored aspects of nocturnal animal behavior, and to produce information that may be used to reduce detrimental effects of human activities to wildlife.
Below are data or web applications associated with this project.
Oahu multi-state occupancy models of foraging habitat use by Hawaiian hoary bats 2017
Below are multimedia items associated with this project.
This clip shows a bat (not identified to species) flying near a turbine as imaged with a thermal camera. The recording shows the bat making numerous repeated passes behind the rotor swept area of a turbine. This activity is of particular interest to researchers because it provides a window into behavior that places bats at risk from turbine strikes.
This clip shows a bat (not identified to species) flying near a turbine as imaged with a camera sensitive to near infrared light. The bat flies in rapidly from the top left, then turns and flies into the spinning rotor blades of the turbine. The bat appears to be deflected upwards by the blades and escapes a direct strike.
This clip shows a bat (not identified to species) flying near a turbine as imaged with a camera sensitive to near infrared light. The bat flies in rapidly from the top left, then turns and flies into the spinning rotor blades of the turbine. The bat appears to be deflected upwards by the blades and escapes a direct strike.
This clip shows a pair of wedge-tailed shearwaters (Puffinus pacificus) as imaged with a camera sensitive to near infrared light. The shearwaters appear out of the night sky at a distance of about 100 meters, and fly along the coast directly towards the camera. This clip demonstrates the application of high-resolution cameras to image nocturnal seabird activity.
This clip shows a pair of wedge-tailed shearwaters (Puffinus pacificus) as imaged with a camera sensitive to near infrared light. The shearwaters appear out of the night sky at a distance of about 100 meters, and fly along the coast directly towards the camera. This clip demonstrates the application of high-resolution cameras to image nocturnal seabird activity.
Bats at Turbines (B-roll): Surveillance video (B-roll) from a temperature-imaging camera showing a bat interacting with a wind turbine at about 3 a.m. on a brightly moonlit night in late August.[video resolution 614 by 454 pixels, limited by imaging device]
Bats at Turbines (B-roll): Surveillance video (B-roll) from a temperature-imaging camera showing a bat interacting with a wind turbine at about 3 a.m. on a brightly moonlit night in late August.[video resolution 614 by 454 pixels, limited by imaging device]
Below are publications associated with this project.
Multi-state occupancy models of foraging habitat use by the Hawaiian hoary bat Lasiurus cinereus semotus
Do you hear what I see? Vocalization relative to visual detection rates of Hawaiian hoary bats (Lasiurus cinereus semotus)
Dim ultraviolet light as a means of deterring activity by the Hawaiian hoary bat Lasiurus cinereus semotus
Ultraviolet vision may be widespread in bats
Behavior of the Hawaiian Hawaiian Hoary Bat (Lasiurus cinereus semotus) at wind turbines and its distribution across the North Ko'olau Mountains, O'ahu
Behavior of bats at wind turbines
Below are news stories associated with this project.
Below are partners associated with this project.
The rapid expansion of wind energy nationwide is an important step toward reducing dependence on non-renewable sources of power. However, the magnitude of the wildlife impacts at wind energy facilities is a newly recognized threat, and the cumulative long-term impacts to various bat species are of increasing concern. It is estimated that more than 450,000 bat fatalities now occur each year at wind turbines in the U.S. and Canada (Cryan 2011).
Overview:
The rapid expansion of wind energy nationwide is an important step toward reducing dependence on non-renewable sources of power. However, the magnitude of the wildlife impacts at wind energy facilities is a newly recognized threat, and the cumulative long-term impacts to various bat species are of increasing concern. It is estimated that more than 450,000 bat fatalities now occur each year at wind turbines in the U.S. and Canada (Cryan 2011).
Assessing the risk industrial wind turbines pose to bats is hindered by low light conditions and the cryptic attributes of night-flying animals. With modern wind turbines now reaching as high as 150 m above the ground (equivalent to a 50-story building), there is presently no cost-effective standards for survey methods available for observing and measuring bat occurrence and behavior in the dark at heights and distances relevant to assessing wind-turbine risk. For example, radar and thermal imaging systems cannot always differentiate the types of animals being detected, and ground-based acoustic detectors can only sample up to about 40 meters, well below the turbine rotor-swept zone in which bats and birds are struck.
Monitoring high-flying nocturnal animals that occur intermittently requires sampling sessions of long duration. This need is often best met by deployment of remote technologies, particularly in situations that are unsafe for long-term occupancy by human observers (e.g., offshore environments and airstrips). A major challenge of such technological approaches is developing efficient ways to process and interpret the large amounts of data acquired. Video-based monitoring systems show great promise for monitoring flying nocturnal animals over entire nights and seasons. Motion analysis of digital imagery acquired by thermal infrared cameras has proven effective for quantifying night flights of bats emerging from caves, and thermal cameras have also been used to observe bat activity around turbines, but the techniques have not been combined as yet in an analytically tractable and cost-efficient system for long-term deployment. Our project is working toward producing standardized methods and tools that meet the challenges of successfully measuring bat activity and risks in association with wind turbines and in assessing and predicting bat mortality in conjunction with quantitative models based on improved surveys.
Project Objectives:
We propose to demonstrate a near infra-red (NIR) video system coupled with advanced digital processing and tracking algorithms to process target information for the purposes of assessing nocturnal animal occurrence and behavior. The system will include automated data processing to reduce the burden from imagery review. We will apply the NIR video system to a range of field settings, and validate the approach of detecting and tracking distant cryptic targets for use in monitoring of vertebrate populations. Specifically, we will demonstrate the application of very low-light cameras in combination with NIR illumination. Near-infrared illumination is a suitable lighting source because this wavelength range is not visible to vertebrates and will not affect behavior. Infrared cameras can also image through glass and other clear materials, whereas thermal IR cameras cannot and thus, the NIR system is better suited to weatherproof enclosures for long-term deployment (e.g., marine environments of offshore turbines).
This is the first field validation of NIR videography to nocturnally track and quantify target motion in mixed species settings at distances >100 m, and under realistic operational conditions and long-term deployment scenarios. The method will provide a cost-effective means to track animal activity, assess abundance and detect specific events of interest (e.g., fatality incidents at wind energy facilities; seabird disorientation and “fallout” at bright light sources; etc.). We expect the experimental and numerical endeavors of this work to quantify previously unexplored aspects of nocturnal animal behavior, and to produce information that may be used to reduce detrimental effects of human activities to wildlife.
Below are data or web applications associated with this project.
Oahu multi-state occupancy models of foraging habitat use by Hawaiian hoary bats 2017
Below are multimedia items associated with this project.
This clip shows a bat (not identified to species) flying near a turbine as imaged with a thermal camera. The recording shows the bat making numerous repeated passes behind the rotor swept area of a turbine. This activity is of particular interest to researchers because it provides a window into behavior that places bats at risk from turbine strikes.
This clip shows a bat (not identified to species) flying near a turbine as imaged with a thermal camera. The recording shows the bat making numerous repeated passes behind the rotor swept area of a turbine. This activity is of particular interest to researchers because it provides a window into behavior that places bats at risk from turbine strikes.
This clip shows a bat (not identified to species) flying near a turbine as imaged with a camera sensitive to near infrared light. The bat flies in rapidly from the top left, then turns and flies into the spinning rotor blades of the turbine. The bat appears to be deflected upwards by the blades and escapes a direct strike.
This clip shows a bat (not identified to species) flying near a turbine as imaged with a camera sensitive to near infrared light. The bat flies in rapidly from the top left, then turns and flies into the spinning rotor blades of the turbine. The bat appears to be deflected upwards by the blades and escapes a direct strike.
This clip shows a pair of wedge-tailed shearwaters (Puffinus pacificus) as imaged with a camera sensitive to near infrared light. The shearwaters appear out of the night sky at a distance of about 100 meters, and fly along the coast directly towards the camera. This clip demonstrates the application of high-resolution cameras to image nocturnal seabird activity.
This clip shows a pair of wedge-tailed shearwaters (Puffinus pacificus) as imaged with a camera sensitive to near infrared light. The shearwaters appear out of the night sky at a distance of about 100 meters, and fly along the coast directly towards the camera. This clip demonstrates the application of high-resolution cameras to image nocturnal seabird activity.
Bats at Turbines (B-roll): Surveillance video (B-roll) from a temperature-imaging camera showing a bat interacting with a wind turbine at about 3 a.m. on a brightly moonlit night in late August.[video resolution 614 by 454 pixels, limited by imaging device]
Bats at Turbines (B-roll): Surveillance video (B-roll) from a temperature-imaging camera showing a bat interacting with a wind turbine at about 3 a.m. on a brightly moonlit night in late August.[video resolution 614 by 454 pixels, limited by imaging device]
Below are publications associated with this project.
Multi-state occupancy models of foraging habitat use by the Hawaiian hoary bat Lasiurus cinereus semotus
Do you hear what I see? Vocalization relative to visual detection rates of Hawaiian hoary bats (Lasiurus cinereus semotus)
Dim ultraviolet light as a means of deterring activity by the Hawaiian hoary bat Lasiurus cinereus semotus
Ultraviolet vision may be widespread in bats
Behavior of the Hawaiian Hawaiian Hoary Bat (Lasiurus cinereus semotus) at wind turbines and its distribution across the North Ko'olau Mountains, O'ahu
Behavior of bats at wind turbines
Below are news stories associated with this project.
Below are partners associated with this project.