The Experts below are selected from a list of 7197 Experts worldwide ranked by ideXlab platform
David G. Schmale - One of the best experts on this subject based on the ideXlab platform.
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Cyborg Roaches versus Robotic Insects: Exploring Ethics in Autonomous Systems through Cyborg Roaches and Robotic Insects
The Science Teacher, 2015Co-Authors: Cindy Bohland, Michael Collver, David Lally, David G. SchmaleAbstract:Autonomous vehicles are poised to become part of our everyday lives. Industry experts predict that self-driving cars will be available to the public in three to five years and may account for most passenger cars on the road in the next two decades (Garvin 2014). Pilotless drones can deliver packages (Poeter 2015), apply pesticides to crops (Rohr 2014), and track hazardous agents in the atmosphere (Schmale et al. 2008; Stone 2013). Full-scale, pilotless aircraft may one day transport passengers (Koebler 2013). Autonomous underwater vehicles can efficiently collect oceanographic data (Lam 2012) and help locate plane and boat wreckage (Reidy 2014). [ILLUSTRATION OMITTED] Scientists are now studying ways to integrate similar robotic technology into living organisms. Insect and rodent Cyborgs could one day be used for military intelligence and earthquake rescue operations and as models for neurological studies (Anthes 2013). As this technology spreads, we need to develop scientifically literate citizens to make well-reasoned ethical decisions about it. Complex ethical questions can be answered in different ways through different and equally valid arguments (Paul and Elder 2006). The messy nature of such questions allows teachers to foster critical thinking. In this activity, we asked students, "What are the ethical consequences of introducing autonomous vehicles into society?" This question led to more nuanced scenarios such as: "If your autonomous car is faced with the choice of either harming you or a group of preschool students, what should it do?" and "How do we create autonomous technology that conforms to human ethical values?" i-Cockroaches and RoboRoaches The hands-on component of this unit uses remote-controlled robots and cyborg insects. The i-Cockroach Micro Robot is a remote-controlled robot, and the RoboRoach is a cyborg insect; kits to create RoboRoaches from living cockroaches are sold to promote teaching and learning about neuroscience (see "On the web"). Both technologies are readily available to high school teachers at relatively low cost (Figure 1, p. 28). Purpose and objectives This activity is designed to * introduce students to autonomous vehicle and cyborg animal technology, * allow students to experience engineering challenges related to this technology, * have students analyze ways in which autonomous vehicles and cyborg animals can provide solutions to current problems, and * have students use ethical reasoning to evaluate the proper use, if any, of autonomous vehicles and cyborg animals in the future. After completing this unit, students will be able to * list ways in which autonomous vehicles and cyborg animals can be used now and in the future and * use a consequence map to make decisions using scientific and ethical reasoning. We tested this lesson on a biology class and a robotics class. To prepare, students read the "Robo Revolution" chapter in Frankenstein's Cat: Cuddling up to Biotech's Brave New Beasts (Anthes 2013; Figure 2, p. 29). The chapter describes how insect and rodent Cyborgs could be used for military intelligence and earthquake rescue operations and as animal models to study treatments for brain disorders. The lesson was divided into five segments: * a PowerPoint presentation, * class construction of a consequence map, * a discussion of the "Robo Revolution" chapter, * a hands-on activity, and * a concluding reflection of the lesson. Consequence maps To answer our first question, "What are the ethical consequences of introducing autonomous vehicles into society?" we asked students to create and analyze a consequence map (Ratcliffe and Grace 2003). Consequence maps teach students to distinguish between certain and uncertain consequences and evaluate scientific evidence in light of their personal value judgments by exploring the "what ifs" of a scenario (Ratcliffe and Grace 2003). …
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Wired for Controversy: Cyborg Roaches versus Robotic Insects: Exploring Ethics in Autonomous Systems through Cyborg Roaches and Robotic Insects
The Science Teacher, 2015Co-Authors: Cindy Bohland, Michael Collver, David Lally, David G. SchmaleAbstract:[ILLUSTRATION OMITTED] Autonomous vehicles are poised to become part of our everyday lives. Industry experts predict that self-driving cars will be available to the public in three to five years and may account for most passenger cars on the road in the next two decades (Garvin 2014). Pilotless drones can deliver packages (Poeter 2015), apply pesticides to crops (Rohr 2014), and track hazardous agents in the atmosphere (Schmale et al. 2008; Stone 2013). Full-scale, pilotless aircraft may one day transport passengers (Koebler 2013). Autonomous underwater vehicles can efficiently collect oceanographic data (Lam 2012) and help locate plane and boat wreckage (Reidy 2014). Scientists are now studying ways to integrate similar robotic technology into living organisms. Insect and rodent Cyborgs could one day be used for military intelligence and earthquake rescue operations and as models for neurological studies (Anthes 2013). As this technology spreads, we need to develop scientifically literate citizens to make well-reasoned ethical decisions about it. Complex ethical questions can be answered in different ways through different and equally valid arguments (Paul and Elder 2006). The messy nature of such questions allows teachers to foster critical thinking. In this activity, we asked students, "What are the ethical consequences of introducing autonomous vehicles into society?" This question led to more nuanced scenarios such as: "If your autonomous car is faced with the choice of either harming you or a group of preschool students, what should it do?" and "How do we create autonomous technology that conforms to human ethical values?" i-Cockroaches and RoboRoaches The hands-on component of this unit uses remote-controlled robots and cyborg insects. The i-Cockroach Micro Robot is a remote-controlled robot, and the RoboRoach is a cyborg insect; kits to create RoboRoaches from living cockroaches are sold to promote teaching and learning about neuroscience (see "On the web"). Both technologies are readily available to high school teachers at relatively low cost (Figure 1, p. 28). Purpose and objectives This activity is designed to * introduce students to autonomous vehicle and cyborg animal technology, * allow students to experience engineering challenges related to this technology, * have students analyze ways in which autonomous vehicles and cyborg animals can provide solutions to current problems, and * have students use ethical reasoning to evaluate the proper use, if any, of autonomous vehicles and cyborg animals in the future. After completing this unit, students will be able to * list ways in which autonomous vehicles and cyborg animals can be used now and in the future and * use a consequence map to make decisions using scientific and ethical reasoning. We tested this lesson on a biology class and a robotics class. To prepare, students read the "Robo Revolution" chapter in Frankenstein's Cat: Cuddling up to Biotech's Brave New Beasts (Anthes 2013; Figure 2, p. 29). The chapter describes how insect and rodent Cyborgs could be used for military intelligence and earthquake rescue operations and as animal models to study treatments for brain disorders. The lesson was divided into five segments: a PowerPoint presentation, * class construction of a consequence map, * a discussion of the "Robo Revolution" chapter, * a hands-on activity, and * a concluding reflection of the lesson. Consequence maps To answer our first question, "What are the ethical consequences of introducing autonomous vehicles into society?" we asked students to create and analyze a consequence map (Ratcliffe and Grace 2003). Consequence maps teach students to distinguish between certain and uncertain consequences and evaluate scientific evidence in light oftheir personal value judgments by exploring the "what ifs" of a scenario (Ratcliffe and Grace 2003). …
Cindy Bohland - One of the best experts on this subject based on the ideXlab platform.
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Cyborg Roaches versus Robotic Insects: Exploring Ethics in Autonomous Systems through Cyborg Roaches and Robotic Insects
The Science Teacher, 2015Co-Authors: Cindy Bohland, Michael Collver, David Lally, David G. SchmaleAbstract:Autonomous vehicles are poised to become part of our everyday lives. Industry experts predict that self-driving cars will be available to the public in three to five years and may account for most passenger cars on the road in the next two decades (Garvin 2014). Pilotless drones can deliver packages (Poeter 2015), apply pesticides to crops (Rohr 2014), and track hazardous agents in the atmosphere (Schmale et al. 2008; Stone 2013). Full-scale, pilotless aircraft may one day transport passengers (Koebler 2013). Autonomous underwater vehicles can efficiently collect oceanographic data (Lam 2012) and help locate plane and boat wreckage (Reidy 2014). [ILLUSTRATION OMITTED] Scientists are now studying ways to integrate similar robotic technology into living organisms. Insect and rodent Cyborgs could one day be used for military intelligence and earthquake rescue operations and as models for neurological studies (Anthes 2013). As this technology spreads, we need to develop scientifically literate citizens to make well-reasoned ethical decisions about it. Complex ethical questions can be answered in different ways through different and equally valid arguments (Paul and Elder 2006). The messy nature of such questions allows teachers to foster critical thinking. In this activity, we asked students, "What are the ethical consequences of introducing autonomous vehicles into society?" This question led to more nuanced scenarios such as: "If your autonomous car is faced with the choice of either harming you or a group of preschool students, what should it do?" and "How do we create autonomous technology that conforms to human ethical values?" i-Cockroaches and RoboRoaches The hands-on component of this unit uses remote-controlled robots and cyborg insects. The i-Cockroach Micro Robot is a remote-controlled robot, and the RoboRoach is a cyborg insect; kits to create RoboRoaches from living cockroaches are sold to promote teaching and learning about neuroscience (see "On the web"). Both technologies are readily available to high school teachers at relatively low cost (Figure 1, p. 28). Purpose and objectives This activity is designed to * introduce students to autonomous vehicle and cyborg animal technology, * allow students to experience engineering challenges related to this technology, * have students analyze ways in which autonomous vehicles and cyborg animals can provide solutions to current problems, and * have students use ethical reasoning to evaluate the proper use, if any, of autonomous vehicles and cyborg animals in the future. After completing this unit, students will be able to * list ways in which autonomous vehicles and cyborg animals can be used now and in the future and * use a consequence map to make decisions using scientific and ethical reasoning. We tested this lesson on a biology class and a robotics class. To prepare, students read the "Robo Revolution" chapter in Frankenstein's Cat: Cuddling up to Biotech's Brave New Beasts (Anthes 2013; Figure 2, p. 29). The chapter describes how insect and rodent Cyborgs could be used for military intelligence and earthquake rescue operations and as animal models to study treatments for brain disorders. The lesson was divided into five segments: * a PowerPoint presentation, * class construction of a consequence map, * a discussion of the "Robo Revolution" chapter, * a hands-on activity, and * a concluding reflection of the lesson. Consequence maps To answer our first question, "What are the ethical consequences of introducing autonomous vehicles into society?" we asked students to create and analyze a consequence map (Ratcliffe and Grace 2003). Consequence maps teach students to distinguish between certain and uncertain consequences and evaluate scientific evidence in light of their personal value judgments by exploring the "what ifs" of a scenario (Ratcliffe and Grace 2003). …
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Wired for Controversy: Cyborg Roaches versus Robotic Insects: Exploring Ethics in Autonomous Systems through Cyborg Roaches and Robotic Insects
The Science Teacher, 2015Co-Authors: Cindy Bohland, Michael Collver, David Lally, David G. SchmaleAbstract:[ILLUSTRATION OMITTED] Autonomous vehicles are poised to become part of our everyday lives. Industry experts predict that self-driving cars will be available to the public in three to five years and may account for most passenger cars on the road in the next two decades (Garvin 2014). Pilotless drones can deliver packages (Poeter 2015), apply pesticides to crops (Rohr 2014), and track hazardous agents in the atmosphere (Schmale et al. 2008; Stone 2013). Full-scale, pilotless aircraft may one day transport passengers (Koebler 2013). Autonomous underwater vehicles can efficiently collect oceanographic data (Lam 2012) and help locate plane and boat wreckage (Reidy 2014). Scientists are now studying ways to integrate similar robotic technology into living organisms. Insect and rodent Cyborgs could one day be used for military intelligence and earthquake rescue operations and as models for neurological studies (Anthes 2013). As this technology spreads, we need to develop scientifically literate citizens to make well-reasoned ethical decisions about it. Complex ethical questions can be answered in different ways through different and equally valid arguments (Paul and Elder 2006). The messy nature of such questions allows teachers to foster critical thinking. In this activity, we asked students, "What are the ethical consequences of introducing autonomous vehicles into society?" This question led to more nuanced scenarios such as: "If your autonomous car is faced with the choice of either harming you or a group of preschool students, what should it do?" and "How do we create autonomous technology that conforms to human ethical values?" i-Cockroaches and RoboRoaches The hands-on component of this unit uses remote-controlled robots and cyborg insects. The i-Cockroach Micro Robot is a remote-controlled robot, and the RoboRoach is a cyborg insect; kits to create RoboRoaches from living cockroaches are sold to promote teaching and learning about neuroscience (see "On the web"). Both technologies are readily available to high school teachers at relatively low cost (Figure 1, p. 28). Purpose and objectives This activity is designed to * introduce students to autonomous vehicle and cyborg animal technology, * allow students to experience engineering challenges related to this technology, * have students analyze ways in which autonomous vehicles and cyborg animals can provide solutions to current problems, and * have students use ethical reasoning to evaluate the proper use, if any, of autonomous vehicles and cyborg animals in the future. After completing this unit, students will be able to * list ways in which autonomous vehicles and cyborg animals can be used now and in the future and * use a consequence map to make decisions using scientific and ethical reasoning. We tested this lesson on a biology class and a robotics class. To prepare, students read the "Robo Revolution" chapter in Frankenstein's Cat: Cuddling up to Biotech's Brave New Beasts (Anthes 2013; Figure 2, p. 29). The chapter describes how insect and rodent Cyborgs could be used for military intelligence and earthquake rescue operations and as animal models to study treatments for brain disorders. The lesson was divided into five segments: a PowerPoint presentation, * class construction of a consequence map, * a discussion of the "Robo Revolution" chapter, * a hands-on activity, and * a concluding reflection of the lesson. Consequence maps To answer our first question, "What are the ethical consequences of introducing autonomous vehicles into society?" we asked students to create and analyze a consequence map (Ratcliffe and Grace 2003). Consequence maps teach students to distinguish between certain and uncertain consequences and evaluate scientific evidence in light oftheir personal value judgments by exploring the "what ifs" of a scenario (Ratcliffe and Grace 2003). …
Lissette Olivares - One of the best experts on this subject based on the ideXlab platform.
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Cyborgs/Power + Cyborg/Art = Race, Gender, Class Ciborgs/poder + ciborgs/arte = raza, género, clase
2020Co-Authors: Chris Hables Gray, Steven Mentor, Lissette OlivaresAbstract:A detailed discussion of the role of art in understanding Cyborgs, and the power of art in shaping us. A contextualization of the articles of the special issue of Teknokultura on Cyborgs, power, art, race, gender and class is made. Particular attention is paid to The Acceleration, Prefguration, and Participatory Evolution.
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Cyborgs power cyborg art race gender class
Teknokultura. Revista de Cultura Digital y Movimientos Sociales, 2013Co-Authors: Chris Hables Gray, Steven Mentor, Lissette OlivaresAbstract:A detailed discussion of the role of art in understanding Cyborgs, and the power of art in shaping us. A contextualization of the articles of the special issue of Teknokultura on Cyborgs, power, art, race, gender and class is made. Particular attention is paid to The Acceleration, Prefiguration, and Participatory Evolution.
Michael Collver - One of the best experts on this subject based on the ideXlab platform.
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Cyborg Roaches versus Robotic Insects: Exploring Ethics in Autonomous Systems through Cyborg Roaches and Robotic Insects
The Science Teacher, 2015Co-Authors: Cindy Bohland, Michael Collver, David Lally, David G. SchmaleAbstract:Autonomous vehicles are poised to become part of our everyday lives. Industry experts predict that self-driving cars will be available to the public in three to five years and may account for most passenger cars on the road in the next two decades (Garvin 2014). Pilotless drones can deliver packages (Poeter 2015), apply pesticides to crops (Rohr 2014), and track hazardous agents in the atmosphere (Schmale et al. 2008; Stone 2013). Full-scale, pilotless aircraft may one day transport passengers (Koebler 2013). Autonomous underwater vehicles can efficiently collect oceanographic data (Lam 2012) and help locate plane and boat wreckage (Reidy 2014). [ILLUSTRATION OMITTED] Scientists are now studying ways to integrate similar robotic technology into living organisms. Insect and rodent Cyborgs could one day be used for military intelligence and earthquake rescue operations and as models for neurological studies (Anthes 2013). As this technology spreads, we need to develop scientifically literate citizens to make well-reasoned ethical decisions about it. Complex ethical questions can be answered in different ways through different and equally valid arguments (Paul and Elder 2006). The messy nature of such questions allows teachers to foster critical thinking. In this activity, we asked students, "What are the ethical consequences of introducing autonomous vehicles into society?" This question led to more nuanced scenarios such as: "If your autonomous car is faced with the choice of either harming you or a group of preschool students, what should it do?" and "How do we create autonomous technology that conforms to human ethical values?" i-Cockroaches and RoboRoaches The hands-on component of this unit uses remote-controlled robots and cyborg insects. The i-Cockroach Micro Robot is a remote-controlled robot, and the RoboRoach is a cyborg insect; kits to create RoboRoaches from living cockroaches are sold to promote teaching and learning about neuroscience (see "On the web"). Both technologies are readily available to high school teachers at relatively low cost (Figure 1, p. 28). Purpose and objectives This activity is designed to * introduce students to autonomous vehicle and cyborg animal technology, * allow students to experience engineering challenges related to this technology, * have students analyze ways in which autonomous vehicles and cyborg animals can provide solutions to current problems, and * have students use ethical reasoning to evaluate the proper use, if any, of autonomous vehicles and cyborg animals in the future. After completing this unit, students will be able to * list ways in which autonomous vehicles and cyborg animals can be used now and in the future and * use a consequence map to make decisions using scientific and ethical reasoning. We tested this lesson on a biology class and a robotics class. To prepare, students read the "Robo Revolution" chapter in Frankenstein's Cat: Cuddling up to Biotech's Brave New Beasts (Anthes 2013; Figure 2, p. 29). The chapter describes how insect and rodent Cyborgs could be used for military intelligence and earthquake rescue operations and as animal models to study treatments for brain disorders. The lesson was divided into five segments: * a PowerPoint presentation, * class construction of a consequence map, * a discussion of the "Robo Revolution" chapter, * a hands-on activity, and * a concluding reflection of the lesson. Consequence maps To answer our first question, "What are the ethical consequences of introducing autonomous vehicles into society?" we asked students to create and analyze a consequence map (Ratcliffe and Grace 2003). Consequence maps teach students to distinguish between certain and uncertain consequences and evaluate scientific evidence in light of their personal value judgments by exploring the "what ifs" of a scenario (Ratcliffe and Grace 2003). …
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Wired for Controversy: Cyborg Roaches versus Robotic Insects: Exploring Ethics in Autonomous Systems through Cyborg Roaches and Robotic Insects
The Science Teacher, 2015Co-Authors: Cindy Bohland, Michael Collver, David Lally, David G. SchmaleAbstract:[ILLUSTRATION OMITTED] Autonomous vehicles are poised to become part of our everyday lives. Industry experts predict that self-driving cars will be available to the public in three to five years and may account for most passenger cars on the road in the next two decades (Garvin 2014). Pilotless drones can deliver packages (Poeter 2015), apply pesticides to crops (Rohr 2014), and track hazardous agents in the atmosphere (Schmale et al. 2008; Stone 2013). Full-scale, pilotless aircraft may one day transport passengers (Koebler 2013). Autonomous underwater vehicles can efficiently collect oceanographic data (Lam 2012) and help locate plane and boat wreckage (Reidy 2014). Scientists are now studying ways to integrate similar robotic technology into living organisms. Insect and rodent Cyborgs could one day be used for military intelligence and earthquake rescue operations and as models for neurological studies (Anthes 2013). As this technology spreads, we need to develop scientifically literate citizens to make well-reasoned ethical decisions about it. Complex ethical questions can be answered in different ways through different and equally valid arguments (Paul and Elder 2006). The messy nature of such questions allows teachers to foster critical thinking. In this activity, we asked students, "What are the ethical consequences of introducing autonomous vehicles into society?" This question led to more nuanced scenarios such as: "If your autonomous car is faced with the choice of either harming you or a group of preschool students, what should it do?" and "How do we create autonomous technology that conforms to human ethical values?" i-Cockroaches and RoboRoaches The hands-on component of this unit uses remote-controlled robots and cyborg insects. The i-Cockroach Micro Robot is a remote-controlled robot, and the RoboRoach is a cyborg insect; kits to create RoboRoaches from living cockroaches are sold to promote teaching and learning about neuroscience (see "On the web"). Both technologies are readily available to high school teachers at relatively low cost (Figure 1, p. 28). Purpose and objectives This activity is designed to * introduce students to autonomous vehicle and cyborg animal technology, * allow students to experience engineering challenges related to this technology, * have students analyze ways in which autonomous vehicles and cyborg animals can provide solutions to current problems, and * have students use ethical reasoning to evaluate the proper use, if any, of autonomous vehicles and cyborg animals in the future. After completing this unit, students will be able to * list ways in which autonomous vehicles and cyborg animals can be used now and in the future and * use a consequence map to make decisions using scientific and ethical reasoning. We tested this lesson on a biology class and a robotics class. To prepare, students read the "Robo Revolution" chapter in Frankenstein's Cat: Cuddling up to Biotech's Brave New Beasts (Anthes 2013; Figure 2, p. 29). The chapter describes how insect and rodent Cyborgs could be used for military intelligence and earthquake rescue operations and as animal models to study treatments for brain disorders. The lesson was divided into five segments: a PowerPoint presentation, * class construction of a consequence map, * a discussion of the "Robo Revolution" chapter, * a hands-on activity, and * a concluding reflection of the lesson. Consequence maps To answer our first question, "What are the ethical consequences of introducing autonomous vehicles into society?" we asked students to create and analyze a consequence map (Ratcliffe and Grace 2003). Consequence maps teach students to distinguish between certain and uncertain consequences and evaluate scientific evidence in light oftheir personal value judgments by exploring the "what ifs" of a scenario (Ratcliffe and Grace 2003). …
David Lally - One of the best experts on this subject based on the ideXlab platform.
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Cyborg Roaches versus Robotic Insects: Exploring Ethics in Autonomous Systems through Cyborg Roaches and Robotic Insects
The Science Teacher, 2015Co-Authors: Cindy Bohland, Michael Collver, David Lally, David G. SchmaleAbstract:Autonomous vehicles are poised to become part of our everyday lives. Industry experts predict that self-driving cars will be available to the public in three to five years and may account for most passenger cars on the road in the next two decades (Garvin 2014). Pilotless drones can deliver packages (Poeter 2015), apply pesticides to crops (Rohr 2014), and track hazardous agents in the atmosphere (Schmale et al. 2008; Stone 2013). Full-scale, pilotless aircraft may one day transport passengers (Koebler 2013). Autonomous underwater vehicles can efficiently collect oceanographic data (Lam 2012) and help locate plane and boat wreckage (Reidy 2014). [ILLUSTRATION OMITTED] Scientists are now studying ways to integrate similar robotic technology into living organisms. Insect and rodent Cyborgs could one day be used for military intelligence and earthquake rescue operations and as models for neurological studies (Anthes 2013). As this technology spreads, we need to develop scientifically literate citizens to make well-reasoned ethical decisions about it. Complex ethical questions can be answered in different ways through different and equally valid arguments (Paul and Elder 2006). The messy nature of such questions allows teachers to foster critical thinking. In this activity, we asked students, "What are the ethical consequences of introducing autonomous vehicles into society?" This question led to more nuanced scenarios such as: "If your autonomous car is faced with the choice of either harming you or a group of preschool students, what should it do?" and "How do we create autonomous technology that conforms to human ethical values?" i-Cockroaches and RoboRoaches The hands-on component of this unit uses remote-controlled robots and cyborg insects. The i-Cockroach Micro Robot is a remote-controlled robot, and the RoboRoach is a cyborg insect; kits to create RoboRoaches from living cockroaches are sold to promote teaching and learning about neuroscience (see "On the web"). Both technologies are readily available to high school teachers at relatively low cost (Figure 1, p. 28). Purpose and objectives This activity is designed to * introduce students to autonomous vehicle and cyborg animal technology, * allow students to experience engineering challenges related to this technology, * have students analyze ways in which autonomous vehicles and cyborg animals can provide solutions to current problems, and * have students use ethical reasoning to evaluate the proper use, if any, of autonomous vehicles and cyborg animals in the future. After completing this unit, students will be able to * list ways in which autonomous vehicles and cyborg animals can be used now and in the future and * use a consequence map to make decisions using scientific and ethical reasoning. We tested this lesson on a biology class and a robotics class. To prepare, students read the "Robo Revolution" chapter in Frankenstein's Cat: Cuddling up to Biotech's Brave New Beasts (Anthes 2013; Figure 2, p. 29). The chapter describes how insect and rodent Cyborgs could be used for military intelligence and earthquake rescue operations and as animal models to study treatments for brain disorders. The lesson was divided into five segments: * a PowerPoint presentation, * class construction of a consequence map, * a discussion of the "Robo Revolution" chapter, * a hands-on activity, and * a concluding reflection of the lesson. Consequence maps To answer our first question, "What are the ethical consequences of introducing autonomous vehicles into society?" we asked students to create and analyze a consequence map (Ratcliffe and Grace 2003). Consequence maps teach students to distinguish between certain and uncertain consequences and evaluate scientific evidence in light of their personal value judgments by exploring the "what ifs" of a scenario (Ratcliffe and Grace 2003). …
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Wired for Controversy: Cyborg Roaches versus Robotic Insects: Exploring Ethics in Autonomous Systems through Cyborg Roaches and Robotic Insects
The Science Teacher, 2015Co-Authors: Cindy Bohland, Michael Collver, David Lally, David G. SchmaleAbstract:[ILLUSTRATION OMITTED] Autonomous vehicles are poised to become part of our everyday lives. Industry experts predict that self-driving cars will be available to the public in three to five years and may account for most passenger cars on the road in the next two decades (Garvin 2014). Pilotless drones can deliver packages (Poeter 2015), apply pesticides to crops (Rohr 2014), and track hazardous agents in the atmosphere (Schmale et al. 2008; Stone 2013). Full-scale, pilotless aircraft may one day transport passengers (Koebler 2013). Autonomous underwater vehicles can efficiently collect oceanographic data (Lam 2012) and help locate plane and boat wreckage (Reidy 2014). Scientists are now studying ways to integrate similar robotic technology into living organisms. Insect and rodent Cyborgs could one day be used for military intelligence and earthquake rescue operations and as models for neurological studies (Anthes 2013). As this technology spreads, we need to develop scientifically literate citizens to make well-reasoned ethical decisions about it. Complex ethical questions can be answered in different ways through different and equally valid arguments (Paul and Elder 2006). The messy nature of such questions allows teachers to foster critical thinking. In this activity, we asked students, "What are the ethical consequences of introducing autonomous vehicles into society?" This question led to more nuanced scenarios such as: "If your autonomous car is faced with the choice of either harming you or a group of preschool students, what should it do?" and "How do we create autonomous technology that conforms to human ethical values?" i-Cockroaches and RoboRoaches The hands-on component of this unit uses remote-controlled robots and cyborg insects. The i-Cockroach Micro Robot is a remote-controlled robot, and the RoboRoach is a cyborg insect; kits to create RoboRoaches from living cockroaches are sold to promote teaching and learning about neuroscience (see "On the web"). Both technologies are readily available to high school teachers at relatively low cost (Figure 1, p. 28). Purpose and objectives This activity is designed to * introduce students to autonomous vehicle and cyborg animal technology, * allow students to experience engineering challenges related to this technology, * have students analyze ways in which autonomous vehicles and cyborg animals can provide solutions to current problems, and * have students use ethical reasoning to evaluate the proper use, if any, of autonomous vehicles and cyborg animals in the future. After completing this unit, students will be able to * list ways in which autonomous vehicles and cyborg animals can be used now and in the future and * use a consequence map to make decisions using scientific and ethical reasoning. We tested this lesson on a biology class and a robotics class. To prepare, students read the "Robo Revolution" chapter in Frankenstein's Cat: Cuddling up to Biotech's Brave New Beasts (Anthes 2013; Figure 2, p. 29). The chapter describes how insect and rodent Cyborgs could be used for military intelligence and earthquake rescue operations and as animal models to study treatments for brain disorders. The lesson was divided into five segments: a PowerPoint presentation, * class construction of a consequence map, * a discussion of the "Robo Revolution" chapter, * a hands-on activity, and * a concluding reflection of the lesson. Consequence maps To answer our first question, "What are the ethical consequences of introducing autonomous vehicles into society?" we asked students to create and analyze a consequence map (Ratcliffe and Grace 2003). Consequence maps teach students to distinguish between certain and uncertain consequences and evaluate scientific evidence in light oftheir personal value judgments by exploring the "what ifs" of a scenario (Ratcliffe and Grace 2003). …
