Assess the effect of substance abuse and dependence as it relates to pregnant women. What local support groups-organizations are available in your community? What resources are available to assist patients in getting there?
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tmosphere as the students take a tour through the atmosphere. Teachers can take their students on a virtual tour of museums and the solar system and galaxies. Students can also take part in virtual labs. Virtual Radioactivity Laboratory provides students with virtual labs to probe radioactivity without the risk of being exposed to radioactive material. Virtual Reality Physics Simulation (VRPS) provides virtual reality labs to probe things like wave propagation, ray optics, relative velocity, electric machines and other phenomena in physics. Physics Education Research (PER) provides virtual labs to probe physical laws such as linear motion, circular motion, and collisions (Chih, 2007). In terms of augmented reality, teachers can use augmented reality technology with three-dimensional rendered earth and sun shapes to teach about the relationship between the earth and the sun. In chemistry, augmented reality allows students to see what an atom or a molecule consists of. In biology, augmented reality technology can show what organs of human beings consist of and how they look by watching three-dimensional computer-generated models in the real classroom. In physics, augmented reality allows observing velocity and acceleration of objects that vary in time. Augmented Reality in Math In the field of mathematics, augmented reality can play a major role in subjects like geometry and calculus. One major example of an augmented reality application is Construct3D. Construct3D is designed with three-dimensional geometric construction models. The application allows students and teachers to share a virtual space to construct geometric shapes by wearing head-mounted displays that enable users to overlay computer-generated images onto the real world. Students and teachers can explore properties of curves, surfaces, and other geometric shapes. In the field of calculus, augmented reality plays a major role in visualizing things like graphs of functions of one or two variables and solids of revolution. In Monterrey, Mexico in May 2003, there was a pilot study conducted with engineering students from a Calculus I course in order to describe the actions of a prototype. From the pilot, students were able to cut a solid and observe different curves in space that in turn would give information about the function itself. (Quintero, 2015) Disadvantages of Virtual Reality and Augmented Reality While there are many benefits to virtual reality and augmented reality, there are many barriers to successfully apply this technology to classrooms. Two of the major barriers are time and technical expertise of the technology. Many teachers are not well equipped or trained to deal with the technical issues and problems that may come up when using this new technology. This would lead to teachers needing a high level of support to ensure positive outcomes when using augmented and virtual realities. As of right now, there is a lack of conceptual framework regarding the implementation>
tmosphere as the students take a tour through the atmosphere. Teachers can take their students on a virtual tour of museums and the solar system and galaxies. Students can also take part in virtual labs. Virtual Radioactivity Laboratory provides students with virtual labs to probe radioactivity without the risk of being exposed to radioactive material. Virtual Reality Physics Simulation (VRPS) provides virtual reality labs to probe things like wave propagation, ray optics, relative velocity, electric machines and other phenomena in physics. Physics Education Research (PER) provides virtual labs to probe physical laws such as linear motion, circular motion, and collisions (Chih, 2007). In terms of augmented reality, teachers can use augmented reality technology with three-dimensional rendered earth and sun shapes to teach about the relationship between the earth and the sun. In chemistry, augmented reality allows students to see what an atom or a molecule consists of. In biology, augmented reality technology can show what organs of human beings consist of and how they look by watching three-dimensional computer-generated models in the real classroom. In physics, augmented reality allows observing velocity and acceleration of objects that vary in time. Augmented Reality in Math In the field of mathematics, augmented reality can play a major role in subjects like geometry and calculus. One major example of an augmented reality application is Construct3D. Construct3D is designed with three-dimensional geometric construction models. The application allows students and teachers to share a virtual space to construct geometric shapes by wearing head-mounted displays that enable users to overlay computer-generated images onto the real world. Students and teachers can explore properties of curves, surfaces, and other geometric shapes. In the field of calculus, augmented reality plays a major role in visualizing things like graphs of functions of one or two variables and solids of revolution. In Monterrey, Mexico in May 2003, there was a pilot study conducted with engineering students from a Calculus I course in order to describe the actions of a prototype. From the pilot, students were able to cut a solid and observe different curves in space that in turn would give information about the function itself. (Quintero, 2015) Disadvantages of Virtual Reality and Augmented Reality While there are many benefits to virtual reality and augmented reality, there are many barriers to successfully apply this technology to classrooms. Two of the major barriers are time and technical expertise of the technology. Many teachers are not well equipped or trained to deal with the technical issues and problems that may come up when using this new technology. This would lead to teachers needing a high level of support to ensure positive outcomes when using augmented and virtual realities. As of right now, there is a lack of conceptual framework regarding the implementation>
