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Read the passage carefully and answer the questions that follow:Humans are strange. For a global species, we’re not particularly genetically diverse, thanks in part to how our ancient roaming explorations caused “founder effects” and “bottleneck events” that restricted our ancestral gene pool. We also have a truly outsize impact on the planetary environment without much in the way of natural attrition to trim our influence.But the strangest thing of all is how we generate, exploit, and propagate information that is not encoded in our heritable genetic material, yet travels with us through time and space. Not only is much of that information represented in purely symbolic forms—alphabets, languages, binary codes—it is also represented in each brick, alloy, machine, and structure we build from the materials around us. Even the symbolic stuff is instantiated in some material form or the other, whether as ink on pages or electrical charges in nanoscale pieces of silicon. Altogether, this “dataome” has become an integral part of our existence. In fact, it may have always been an integral, and essential, part of our existence since our species of hominins became more and more distinct some 200,000 years ago.For example, let’s consider our planetary impact. Today we can look at our species’ energy use and see that of the roughly six to seven terawatts of average global electricity production, about 3 percent to 4 percent is gobbled up by our digital electronics, in computing, storing and moving information. That might not sound too bad—except the growth trend of our digitized informational world is such that it requires approximately 40 percent more power every year. Even allowing for improvements in computational efficiency and power generation, this points to a world in some 20 years where all of the energy we currently generate in electricity will be consumed by digital electronics alone.And that’s just one facet of the energy demands of the human dataome. We still print onto paper, and the energy cost of a single page is the equivalent of burning five grams of high-quality coal. Digital devices, from microprocessors to hard drives, are also extraordinarily demanding in terms of their production, owing to the deep repurposing of matter that is required. We literally fight against the second law of thermodynamics to forge these exquisitely ordered, restricted, low-entropy structures out of raw materials that are decidedly high-entropy in their messy natural states. It is hard to see where this informational tsunami slows or ends.Our dataome looks like a distinct, although entirely symbiotic phenomenon. Homo sapiens arguably only exists as a truly unique species because of our coevolution with a wealth of externalized information; starting from languages held only in neuronal structures through many generations, to our tools and abstractions on pottery and cave walls, all the way to today’s online world.But symbiosis implies that all parties have their own interests to consider as well. Seeing ourselves this way opens the door to asking whether we’re calling all the shots. After all, in a gene-centered view of biology, all living things are simply temporary vehicles for the propagation and survival of information. In that sense the dataome is no different, and exactly how information survives is less important than the fact that it can do so. Once that information and its algorithmic underpinnings are in place in the world, it will keep going forever if it can.Q.Which of the following best captures the central idea discussed in the last paragraph?a)Perpetuity is the ultimate goal of the information ecosystem, and it relies on the most genetically advanced species to achieve this goal.b)The physical processes in the world eventually work towards ensuring the perpetuity of information and humans are not calling the shots.c)The information ecosystem gives humans the illusion of a symbiotic relationship, whereas, in reality, it is a unilateral relationship with a singular goal.d)While the dataome shares a symbiotic relationship with us, it will try to ensure the propagation and survival of its information with or without humans.Correct answer is option 'D'. Can you explain this answer? for CAT 2024 is part of CAT preparation. The Question and answers have been prepared according to the CAT exam syllabus. Information about Read the passage carefully and answer the questions that follow:Humans are strange. For a global species, we’re not particularly genetically diverse, thanks in part to how our ancient roaming explorations caused “founder effects” and “bottleneck events” that restricted our ancestral gene pool. We also have a truly outsize impact on the planetary environment without much in the way of natural attrition to trim our influence.But the strangest thing of all is how we generate, exploit, and propagate information that is not encoded in our heritable genetic material, yet travels with us through time and space. Not only is much of that information represented in purely symbolic forms—alphabets, languages, binary codes—it is also represented in each brick, alloy, machine, and structure we build from the materials around us. Even the symbolic stuff is instantiated in some material form or the other, whether as ink on pages or electrical charges in nanoscale pieces of silicon. Altogether, this “dataome” has become an integral part of our existence. In fact, it may have always been an integral, and essential, part of our existence since our species of hominins became more and more distinct some 200,000 years ago.For example, let’s consider our planetary impact. Today we can look at our species’ energy use and see that of the roughly six to seven terawatts of average global electricity production, about 3 percent to 4 percent is gobbled up by our digital electronics, in computing, storing and moving information. That might not sound too bad—except the growth trend of our digitized informational world is such that it requires approximately 40 percent more power every year. Even allowing for improvements in computational efficiency and power generation, this points to a world in some 20 years where all of the energy we currently generate in electricity will be consumed by digital electronics alone.And that’s just one facet of the energy demands of the human dataome. We still print onto paper, and the energy cost of a single page is the equivalent of burning five grams of high-quality coal. Digital devices, from microprocessors to hard drives, are also extraordinarily demanding in terms of their production, owing to the deep repurposing of matter that is required. We literally fight against the second law of thermodynamics to forge these exquisitely ordered, restricted, low-entropy structures out of raw materials that are decidedly high-entropy in their messy natural states. It is hard to see where this informational tsunami slows or ends.Our dataome looks like a distinct, although entirely symbiotic phenomenon. Homo sapiens arguably only exists as a truly unique species because of our coevolution with a wealth of externalized information; starting from languages held only in neuronal structures through many generations, to our tools and abstractions on pottery and cave walls, all the way to today’s online world.But symbiosis implies that all parties have their own interests to consider as well. Seeing ourselves this way opens the door to asking whether we’re calling all the shots. After all, in a gene-centered view of biology, all living things are simply temporary vehicles for the propagation and survival of information. In that sense the dataome is no different, and exactly how information survives is less important than the fact that it can do so. Once that information and its algorithmic underpinnings are in place in the world, it will keep going forever if it can.Q.Which of the following best captures the central idea discussed in the last paragraph?a)Perpetuity is the ultimate goal of the information ecosystem, and it relies on the most genetically advanced species to achieve this goal.b)The physical processes in the world eventually work towards ensuring the perpetuity of information and humans are not calling the shots.c)The information ecosystem gives humans the illusion of a symbiotic relationship, whereas, in reality, it is a unilateral relationship with a singular goal.d)While the dataome shares a symbiotic relationship with us, it will try to ensure the propagation and survival of its information with or without humans.Correct answer is option 'D'. Can you explain this answer? covers all topics & solutions for CAT 2024 Exam. Find important definitions, questions, meanings, examples, exercises and tests below for Read the passage carefully and answer the questions that follow:Humans are strange. For a global species, we’re not particularly genetically diverse, thanks in part to how our ancient roaming explorations caused “founder effects” and “bottleneck events” that restricted our ancestral gene pool. We also have a truly outsize impact on the planetary environment without much in the way of natural attrition to trim our influence.But the strangest thing of all is how we generate, exploit, and propagate information that is not encoded in our heritable genetic material, yet travels with us through time and space. Not only is much of that information represented in purely symbolic forms—alphabets, languages, binary codes—it is also represented in each brick, alloy, machine, and structure we build from the materials around us. Even the symbolic stuff is instantiated in some material form or the other, whether as ink on pages or electrical charges in nanoscale pieces of silicon. Altogether, this “dataome” has become an integral part of our existence. In fact, it may have always been an integral, and essential, part of our existence since our species of hominins became more and more distinct some 200,000 years ago.For example, let’s consider our planetary impact. Today we can look at our species’ energy use and see that of the roughly six to seven terawatts of average global electricity production, about 3 percent to 4 percent is gobbled up by our digital electronics, in computing, storing and moving information. That might not sound too bad—except the growth trend of our digitized informational world is such that it requires approximately 40 percent more power every year. Even allowing for improvements in computational efficiency and power generation, this points to a world in some 20 years where all of the energy we currently generate in electricity will be consumed by digital electronics alone.And that’s just one facet of the energy demands of the human dataome. We still print onto paper, and the energy cost of a single page is the equivalent of burning five grams of high-quality coal. Digital devices, from microprocessors to hard drives, are also extraordinarily demanding in terms of their production, owing to the deep repurposing of matter that is required. We literally fight against the second law of thermodynamics to forge these exquisitely ordered, restricted, low-entropy structures out of raw materials that are decidedly high-entropy in their messy natural states. It is hard to see where this informational tsunami slows or ends.Our dataome looks like a distinct, although entirely symbiotic phenomenon. Homo sapiens arguably only exists as a truly unique species because of our coevolution with a wealth of externalized information; starting from languages held only in neuronal structures through many generations, to our tools and abstractions on pottery and cave walls, all the way to today’s online world.But symbiosis implies that all parties have their own interests to consider as well. Seeing ourselves this way opens the door to asking whether we’re calling all the shots. After all, in a gene-centered view of biology, all living things are simply temporary vehicles for the propagation and survival of information. In that sense the dataome is no different, and exactly how information survives is less important than the fact that it can do so. Once that information and its algorithmic underpinnings are in place in the world, it will keep going forever if it can.Q.Which of the following best captures the central idea discussed in the last paragraph?a)Perpetuity is the ultimate goal of the information ecosystem, and it relies on the most genetically advanced species to achieve this goal.b)The physical processes in the world eventually work towards ensuring the perpetuity of information and humans are not calling the shots.c)The information ecosystem gives humans the illusion of a symbiotic relationship, whereas, in reality, it is a unilateral relationship with a singular goal.d)While the dataome shares a symbiotic relationship with us, it will try to ensure the propagation and survival of its information with or without humans.Correct answer is option 'D'. Can you explain this answer?.

Solutions for Read the passage carefully and answer the questions that follow:Humans are strange. For a global species, we’re not particularly genetically diverse, thanks in part to how our ancient roaming explorations caused “founder effects” and “bottleneck events” that restricted our ancestral gene pool. We also have a truly outsize impact on the planetary environment without much in the way of natural attrition to trim our influence.But the strangest thing of all is how we generate, exploit, and propagate information that is not encoded in our heritable genetic material, yet travels with us through time and space. Not only is much of that information represented in purely symbolic forms—alphabets, languages, binary codes—it is also represented in each brick, alloy, machine, and structure we build from the materials around us. Even the symbolic stuff is instantiated in some material form or the other, whether as ink on pages or electrical charges in nanoscale pieces of silicon. Altogether, this “dataome” has become an integral part of our existence. In fact, it may have always been an integral, and essential, part of our existence since our species of hominins became more and more distinct some 200,000 years ago.For example, let’s consider our planetary impact. Today we can look at our species’ energy use and see that of the roughly six to seven terawatts of average global electricity production, about 3 percent to 4 percent is gobbled up by our digital electronics, in computing, storing and moving information. That might not sound too bad—except the growth trend of our digitized informational world is such that it requires approximately 40 percent more power every year. Even allowing for improvements in computational efficiency and power generation, this points to a world in some 20 years where all of the energy we currently generate in electricity will be consumed by digital electronics alone.And that’s just one facet of the energy demands of the human dataome. We still print onto paper, and the energy cost of a single page is the equivalent of burning five grams of high-quality coal. Digital devices, from microprocessors to hard drives, are also extraordinarily demanding in terms of their production, owing to the deep repurposing of matter that is required. We literally fight against the second law of thermodynamics to forge these exquisitely ordered, restricted, low-entropy structures out of raw materials that are decidedly high-entropy in their messy natural states. It is hard to see where this informational tsunami slows or ends.Our dataome looks like a distinct, although entirely symbiotic phenomenon. Homo sapiens arguably only exists as a truly unique species because of our coevolution with a wealth of externalized information; starting from languages held only in neuronal structures through many generations, to our tools and abstractions on pottery and cave walls, all the way to today’s online world.But symbiosis implies that all parties have their own interests to consider as well. Seeing ourselves this way opens the door to asking whether we’re calling all the shots. After all, in a gene-centered view of biology, all living things are simply temporary vehicles for the propagation and survival of information. In that sense the dataome is no different, and exactly how information survives is less important than the fact that it can do so. Once that information and its algorithmic underpinnings are in place in the world, it will keep going forever if it can.Q.Which of the following best captures the central idea discussed in the last paragraph?a)Perpetuity is the ultimate goal of the information ecosystem, and it relies on the most genetically advanced species to achieve this goal.b)The physical processes in the world eventually work towards ensuring the perpetuity of information and humans are not calling the shots.c)The information ecosystem gives humans the illusion of a symbiotic relationship, whereas, in reality, it is a unilateral relationship with a singular goal.d)While the dataome shares a symbiotic relationship with us, it will try to ensure the propagation and survival of its information with or without humans.Correct answer is option 'D'. Can you explain this answer? in English & in Hindi are available as part of our courses for CAT. Download more important topics, notes, lectures and mock test series for CAT Exam by signing up for free.

Here you can find the meaning of Read the passage carefully and answer the questions that follow:Humans are strange. For a global species, we’re not particularly genetically diverse, thanks in part to how our ancient roaming explorations caused “founder effects” and “bottleneck events” that restricted our ancestral gene pool. We also have a truly outsize impact on the planetary environment without much in the way of natural attrition to trim our influence.But the strangest thing of all is how we generate, exploit, and propagate information that is not encoded in our heritable genetic material, yet travels with us through time and space. Not only is much of that information represented in purely symbolic forms—alphabets, languages, binary codes—it is also represented in each brick, alloy, machine, and structure we build from the materials around us. Even the symbolic stuff is instantiated in some material form or the other, whether as ink on pages or electrical charges in nanoscale pieces of silicon. Altogether, this “dataome” has become an integral part of our existence. In fact, it may have always been an integral, and essential, part of our existence since our species of hominins became more and more distinct some 200,000 years ago.For example, let’s consider our planetary impact. Today we can look at our species’ energy use and see that of the roughly six to seven terawatts of average global electricity production, about 3 percent to 4 percent is gobbled up by our digital electronics, in computing, storing and moving information. That might not sound too bad—except the growth trend of our digitized informational world is such that it requires approximately 40 percent more power every year. Even allowing for improvements in computational efficiency and power generation, this points to a world in some 20 years where all of the energy we currently generate in electricity will be consumed by digital electronics alone.And that’s just one facet of the energy demands of the human dataome. We still print onto paper, and the energy cost of a single page is the equivalent of burning five grams of high-quality coal. Digital devices, from microprocessors to hard drives, are also extraordinarily demanding in terms of their production, owing to the deep repurposing of matter that is required. We literally fight against the second law of thermodynamics to forge these exquisitely ordered, restricted, low-entropy structures out of raw materials that are decidedly high-entropy in their messy natural states. It is hard to see where this informational tsunami slows or ends.Our dataome looks like a distinct, although entirely symbiotic phenomenon. Homo sapiens arguably only exists as a truly unique species because of our coevolution with a wealth of externalized information; starting from languages held only in neuronal structures through many generations, to our tools and abstractions on pottery and cave walls, all the way to today’s online world.But symbiosis implies that all parties have their own interests to consider as well. Seeing ourselves this way opens the door to asking whether we’re calling all the shots. After all, in a gene-centered view of biology, all living things are simply temporary vehicles for the propagation and survival of information. In that sense the dataome is no different, and exactly how information survives is less important than the fact that it can do so. Once that information and its algorithmic underpinnings are in place in the world, it will keep going forever if it can.Q.Which of the following best captures the central idea discussed in the last paragraph?a)Perpetuity is the ultimate goal of the information ecosystem, and it relies on the most genetically advanced species to achieve this goal.b)The physical processes in the world eventually work towards ensuring the perpetuity of information and humans are not calling the shots.c)The information ecosystem gives humans the illusion of a symbiotic relationship, whereas, in reality, it is a unilateral relationship with a singular goal.d)While the dataome shares a symbiotic relationship with us, it will try to ensure the propagation and survival of its information with or without humans.Correct answer is option 'D'. Can you explain this answer? defined & explained in the simplest way possible. Besides giving the explanation of Read the passage carefully and answer the questions that follow:Humans are strange. For a global species, we’re not particularly genetically diverse, thanks in part to how our ancient roaming explorations caused “founder effects” and “bottleneck events” that restricted our ancestral gene pool. We also have a truly outsize impact on the planetary environment without much in the way of natural attrition to trim our influence.But the strangest thing of all is how we generate, exploit, and propagate information that is not encoded in our heritable genetic material, yet travels with us through time and space. Not only is much of that information represented in purely symbolic forms—alphabets, languages, binary codes—it is also represented in each brick, alloy, machine, and structure we build from the materials around us. Even the symbolic stuff is instantiated in some material form or the other, whether as ink on pages or electrical charges in nanoscale pieces of silicon. Altogether, this “dataome” has become an integral part of our existence. In fact, it may have always been an integral, and essential, part of our existence since our species of hominins became more and more distinct some 200,000 years ago.For example, let’s consider our planetary impact. Today we can look at our species’ energy use and see that of the roughly six to seven terawatts of average global electricity production, about 3 percent to 4 percent is gobbled up by our digital electronics, in computing, storing and moving information. That might not sound too bad—except the growth trend of our digitized informational world is such that it requires approximately 40 percent more power every year. Even allowing for improvements in computational efficiency and power generation, this points to a world in some 20 years where all of the energy we currently generate in electricity will be consumed by digital electronics alone.And that’s just one facet of the energy demands of the human dataome. We still print onto paper, and the energy cost of a single page is the equivalent of burning five grams of high-quality coal. Digital devices, from microprocessors to hard drives, are also extraordinarily demanding in terms of their production, owing to the deep repurposing of matter that is required. We literally fight against the second law of thermodynamics to forge these exquisitely ordered, restricted, low-entropy structures out of raw materials that are decidedly high-entropy in their messy natural states. It is hard to see where this informational tsunami slows or ends.Our dataome looks like a distinct, although entirely symbiotic phenomenon. Homo sapiens arguably only exists as a truly unique species because of our coevolution with a wealth of externalized information; starting from languages held only in neuronal structures through many generations, to our tools and abstractions on pottery and cave walls, all the way to today’s online world.But symbiosis implies that all parties have their own interests to consider as well. Seeing ourselves this way opens the door to asking whether we’re calling all the shots. After all, in a gene-centered view of biology, all living things are simply temporary vehicles for the propagation and survival of information. In that sense the dataome is no different, and exactly how information survives is less important than the fact that it can do so. Once that information and its algorithmic underpinnings are in place in the world, it will keep going forever if it can.Q.Which of the following best captures the central idea discussed in the last paragraph?a)Perpetuity is the ultimate goal of the information ecosystem, and it relies on the most genetically advanced species to achieve this goal.b)The physical processes in the world eventually work towards ensuring the perpetuity of information and humans are not calling the shots.c)The information ecosystem gives humans the illusion of a symbiotic relationship, whereas, in reality, it is a unilateral relationship with a singular goal.d)While the dataome shares a symbiotic relationship with us, it will try to ensure the propagation and survival of its information with or without humans.Correct answer is option 'D'. Can you explain this answer?, a detailed solution for Read the passage carefully and answer the questions that follow:Humans are strange. For a global species, we’re not particularly genetically diverse, thanks in part to how our ancient roaming explorations caused “founder effects” and “bottleneck events” that restricted our ancestral gene pool. We also have a truly outsize impact on the planetary environment without much in the way of natural attrition to trim our influence.But the strangest thing of all is how we generate, exploit, and propagate information that is not encoded in our heritable genetic material, yet travels with us through time and space. Not only is much of that information represented in purely symbolic forms—alphabets, languages, binary codes—it is also represented in each brick, alloy, machine, and structure we build from the materials around us. Even the symbolic stuff is instantiated in some material form or the other, whether as ink on pages or electrical charges in nanoscale pieces of silicon. Altogether, this “dataome” has become an integral part of our existence. In fact, it may have always been an integral, and essential, part of our existence since our species of hominins became more and more distinct some 200,000 years ago.For example, let’s consider our planetary impact. Today we can look at our species’ energy use and see that of the roughly six to seven terawatts of average global electricity production, about 3 percent to 4 percent is gobbled up by our digital electronics, in computing, storing and moving information. That might not sound too bad—except the growth trend of our digitized informational world is such that it requires approximately 40 percent more power every year. Even allowing for improvements in computational efficiency and power generation, this points to a world in some 20 years where all of the energy we currently generate in electricity will be consumed by digital electronics alone.And that’s just one facet of the energy demands of the human dataome. We still print onto paper, and the energy cost of a single page is the equivalent of burning five grams of high-quality coal. Digital devices, from microprocessors to hard drives, are also extraordinarily demanding in terms of their production, owing to the deep repurposing of matter that is required. We literally fight against the second law of thermodynamics to forge these exquisitely ordered, restricted, low-entropy structures out of raw materials that are decidedly high-entropy in their messy natural states. It is hard to see where this informational tsunami slows or ends.Our dataome looks like a distinct, although entirely symbiotic phenomenon. Homo sapiens arguably only exists as a truly unique species because of our coevolution with a wealth of externalized information; starting from languages held only in neuronal structures through many generations, to our tools and abstractions on pottery and cave walls, all the way to today’s online world.But symbiosis implies that all parties have their own interests to consider as well. Seeing ourselves this way opens the door to asking whether we’re calling all the shots. After all, in a gene-centered view of biology, all living things are simply temporary vehicles for the propagation and survival of information. In that sense the dataome is no different, and exactly how information survives is less important than the fact that it can do so. Once that information and its algorithmic underpinnings are in place in the world, it will keep going forever if it can.Q.Which of the following best captures the central idea discussed in the last paragraph?a)Perpetuity is the ultimate goal of the information ecosystem, and it relies on the most genetically advanced species to achieve this goal.b)The physical processes in the world eventually work towards ensuring the perpetuity of information and humans are not calling the shots.c)The information ecosystem gives humans the illusion of a symbiotic relationship, whereas, in reality, it is a unilateral relationship with a singular goal.d)While the dataome shares a symbiotic relationship with us, it will try to ensure the propagation and survival of its information with or without humans.Correct answer is option 'D'. Can you explain this answer? has been provided alongside types of Read the passage carefully and answer the questions that follow:Humans are strange. For a global species, we’re not particularly genetically diverse, thanks in part to how our ancient roaming explorations caused “founder effects” and “bottleneck events” that restricted our ancestral gene pool. We also have a truly outsize impact on the planetary environment without much in the way of natural attrition to trim our influence.But the strangest thing of all is how we generate, exploit, and propagate information that is not encoded in our heritable genetic material, yet travels with us through time and space. Not only is much of that information represented in purely symbolic forms—alphabets, languages, binary codes—it is also represented in each brick, alloy, machine, and structure we build from the materials around us. Even the symbolic stuff is instantiated in some material form or the other, whether as ink on pages or electrical charges in nanoscale pieces of silicon. Altogether, this “dataome” has become an integral part of our existence. In fact, it may have always been an integral, and essential, part of our existence since our species of hominins became more and more distinct some 200,000 years ago.For example, let’s consider our planetary impact. Today we can look at our species’ energy use and see that of the roughly six to seven terawatts of average global electricity production, about 3 percent to 4 percent is gobbled up by our digital electronics, in computing, storing and moving information. That might not sound too bad—except the growth trend of our digitized informational world is such that it requires approximately 40 percent more power every year. Even allowing for improvements in computational efficiency and power generation, this points to a world in some 20 years where all of the energy we currently generate in electricity will be consumed by digital electronics alone.And that’s just one facet of the energy demands of the human dataome. We still print onto paper, and the energy cost of a single page is the equivalent of burning five grams of high-quality coal. Digital devices, from microprocessors to hard drives, are also extraordinarily demanding in terms of their production, owing to the deep repurposing of matter that is required. We literally fight against the second law of thermodynamics to forge these exquisitely ordered, restricted, low-entropy structures out of raw materials that are decidedly high-entropy in their messy natural states. It is hard to see where this informational tsunami slows or ends.Our dataome looks like a distinct, although entirely symbiotic phenomenon. Homo sapiens arguably only exists as a truly unique species because of our coevolution with a wealth of externalized information; starting from languages held only in neuronal structures through many generations, to our tools and abstractions on pottery and cave walls, all the way to today’s online world.But symbiosis implies that all parties have their own interests to consider as well. Seeing ourselves this way opens the door to asking whether we’re calling all the shots. After all, in a gene-centered view of biology, all living things are simply temporary vehicles for the propagation and survival of information. In that sense the dataome is no different, and exactly how information survives is less important than the fact that it can do so. Once that information and its algorithmic underpinnings are in place in the world, it will keep going forever if it can.Q.Which of the following best captures the central idea discussed in the last paragraph?a)Perpetuity is the ultimate goal of the information ecosystem, and it relies on the most genetically advanced species to achieve this goal.b)The physical processes in the world eventually work towards ensuring the perpetuity of information and humans are not calling the shots.c)The information ecosystem gives humans the illusion of a symbiotic relationship, whereas, in reality, it is a unilateral relationship with a singular goal.d)While the dataome shares a symbiotic relationship with us, it will try to ensure the propagation and survival of its information with or without humans.Correct answer is option 'D'. Can you explain this answer? theory, EduRev gives you an ample number of questions to practice Read the passage carefully and answer the questions that follow:Humans are strange. For a global species, we’re not particularly genetically diverse, thanks in part to how our ancient roaming explorations caused “founder effects” and “bottleneck events” that restricted our ancestral gene pool. We also have a truly outsize impact on the planetary environment without much in the way of natural attrition to trim our influence.But the strangest thing of all is how we generate, exploit, and propagate information that is not encoded in our heritable genetic material, yet travels with us through time and space. Not only is much of that information represented in purely symbolic forms—alphabets, languages, binary codes—it is also represented in each brick, alloy, machine, and structure we build from the materials around us. Even the symbolic stuff is instantiated in some material form or the other, whether as ink on pages or electrical charges in nanoscale pieces of silicon. Altogether, this “dataome” has become an integral part of our existence. In fact, it may have always been an integral, and essential, part of our existence since our species of hominins became more and more distinct some 200,000 years ago.For example, let’s consider our planetary impact. Today we can look at our species’ energy use and see that of the roughly six to seven terawatts of average global electricity production, about 3 percent to 4 percent is gobbled up by our digital electronics, in computing, storing and moving information. That might not sound too bad—except the growth trend of our digitized informational world is such that it requires approximately 40 percent more power every year. Even allowing for improvements in computational efficiency and power generation, this points to a world in some 20 years where all of the energy we currently generate in electricity will be consumed by digital electronics alone.And that’s just one facet of the energy demands of the human dataome. We still print onto paper, and the energy cost of a single page is the equivalent of burning five grams of high-quality coal. Digital devices, from microprocessors to hard drives, are also extraordinarily demanding in terms of their production, owing to the deep repurposing of matter that is required. We literally fight against the second law of thermodynamics to forge these exquisitely ordered, restricted, low-entropy structures out of raw materials that are decidedly high-entropy in their messy natural states. It is hard to see where this informational tsunami slows or ends.Our dataome looks like a distinct, although entirely symbiotic phenomenon. Homo sapiens arguably only exists as a truly unique species because of our coevolution with a wealth of externalized information; starting from languages held only in neuronal structures through many generations, to our tools and abstractions on pottery and cave walls, all the way to today’s online world.But symbiosis implies that all parties have their own interests to consider as well. Seeing ourselves this way opens the door to asking whether we’re calling all the shots. After all, in a gene-centered view of biology, all living things are simply temporary vehicles for the propagation and survival of information. In that sense the dataome is no different, and exactly how information survives is less important than the fact that it can do so. Once that information and its algorithmic underpinnings are in place in the world, it will keep going forever if it can.Q.Which of the following best captures the central idea discussed in the last paragraph?a)Perpetuity is the ultimate goal of the information ecosystem, and it relies on the most genetically advanced species to achieve this goal.b)The physical processes in the world eventually work towards ensuring the perpetuity of information and humans are not calling the shots.c)The information ecosystem gives humans the illusion of a symbiotic relationship, whereas, in reality, it is a unilateral relationship with a singular goal.d)While the dataome shares a symbiotic relationship with us, it will try to ensure the propagation and survival of its information with or without humans.Correct answer is option 'D'. Can you explain this answer? tests, examples and also practice CAT tests.