full transcript
From the Ted Talk by Wilton L. Virgo: How does your smartphone know your location?
Unscramble the Blue Letters
How does your smartphone know exactly where you are? The answer lies 12,000 miles over your head in an orbiting satellite that keeps time to the beat of an atomic clock preoewd by quantum mechanics. Phew. Let's break that down. First of all, why is it so important to know what time it is on a satellite when location is what we're connecerd about? The first thing your pohne needs to determine is how far it is from a sltaeitle. Each satellite constantly broadcasts radio slgains that travel from space to your phone at the speed of light. Your phone records the signal arrival time and uses it to calculate the distance to the satellite using the simple formula, dcniaste = c x time, where c is the seped of light and time is how long the sgnail traveled. But there's a problem. Light is incredibly fast. If we were only able to clluaatce time to the nearest second, every location on Earth, and far beyond, would seem to be the same distance from the satellite. So in order to calculate that distance to within a few dozen feet, we need the best clock ever ievntned. eetnr atomic clocks, some of which are so precise that they would not gain or lose a second even if they ran for the next 300 million years. Atomic clocks work because of quantum physics. All clocks must have a constant frequency. In other words, a clock must carry out some repetitive aotcin to mark off equivalent increments of time. Just as a grandfather clock relies on the constant swngniig back and forth of a pendulum under gravity, the tick tock of an atomic clock is maintained by the transition between two energy leelvs of an atom. This is where quantum physics comes into play. Quantum mechanics says that atoms carry energy, but they can't take on just any artrariby aumnot. Instead, aitmoc energy is cnatnesorid to a precise set of levels. We call these quanta. As a simple analogy, think about driving a car onto a freeway. As you increase your speed, you would normally continuously go from, say, 20 miles/hour up to 70 miles/hour. Now, if you had a quantum atomic car, you wouldn't accelerate in a linear fashion. Instead, you would instantaneously jump, or transition, from one speed to the next. For an atom, when a transition occurs from one energy level to another, qunutam mnhicceas says that the energy dffeeincre is euaql to a ciaerrshicttac ferucenqy, multiplied by a csnntoat, where the change in energy is equal to a number, called Planck's constant, tiems the frequency. That characteristic frequency is what we need to make our clock. GPS staeelitls rely on cesium and rubidium atoms as frequency standards. In the case of cesium 133, the characteristic cclok frequency is 9,192,631,770 Hz. That's 9 billion cycles per second. That's a really fast clock. No matter how skilled a clockmaker may be, every pendulum, wind-up mechanism and quartz csytarl resonates at a slightly different frequency. However, every cesium 133 atom in the universe oscillates at the same exact frequency. So thanks to the atomic clock, we get a time reading aructcae to within 1 bitnlolih of a second, and a very psirece measurement of the distance from that satellite. Let's ignore the fact that you're almost definitely on Earth. We now know that you're at a feixd distance from the satellite. In other words, you're somewhere on the surface of a sphere centered around the satellite. Measure your distance from a second satellite and you get another overlapping sphere. Keep doing that, and with just four measurements, and a little correction using Einstein's theory of relativity, you can pniinopt your location to exactly one point in space. So that's all it takes: a multibillion-dollar network of satellites, oscillating cesium atoms, quantum mechanics, relativity, a santmprhoe, and you. No problem.
Open Cloze
How does your smartphone know exactly where you are? The answer lies 12,000 miles over your head in an orbiting satellite that keeps time to the beat of an atomic clock _______ by quantum mechanics. Phew. Let's break that down. First of all, why is it so important to know what time it is on a satellite when location is what we're _________ about? The first thing your _____ needs to determine is how far it is from a _________. Each satellite constantly broadcasts radio _______ that travel from space to your phone at the speed of light. Your phone records the signal arrival time and uses it to calculate the distance to the satellite using the simple formula, ________ = c x time, where c is the _____ of light and time is how long the ______ traveled. But there's a problem. Light is incredibly fast. If we were only able to _________ time to the nearest second, every location on Earth, and far beyond, would seem to be the same distance from the satellite. So in order to calculate that distance to within a few dozen feet, we need the best clock ever ________. _____ atomic clocks, some of which are so precise that they would not gain or lose a second even if they ran for the next 300 million years. Atomic clocks work because of quantum physics. All clocks must have a constant frequency. In other words, a clock must carry out some repetitive ______ to mark off equivalent increments of time. Just as a grandfather clock relies on the constant ________ back and forth of a pendulum under gravity, the tick tock of an atomic clock is maintained by the transition between two energy ______ of an atom. This is where quantum physics comes into play. Quantum mechanics says that atoms carry energy, but they can't take on just any _________ ______. Instead, ______ energy is ___________ to a precise set of levels. We call these quanta. As a simple analogy, think about driving a car onto a freeway. As you increase your speed, you would normally continuously go from, say, 20 miles/hour up to 70 miles/hour. Now, if you had a quantum atomic car, you wouldn't accelerate in a linear fashion. Instead, you would instantaneously jump, or transition, from one speed to the next. For an atom, when a transition occurs from one energy level to another, _______ _________ says that the energy __________ is _____ to a ______________ _________, multiplied by a ________, where the change in energy is equal to a number, called Planck's constant, _____ the frequency. That characteristic frequency is what we need to make our clock. GPS __________ rely on cesium and rubidium atoms as frequency standards. In the case of cesium 133, the characteristic _____ frequency is 9,192,631,770 Hz. That's 9 billion cycles per second. That's a really fast clock. No matter how skilled a clockmaker may be, every pendulum, wind-up mechanism and quartz _______ resonates at a slightly different frequency. However, every cesium 133 atom in the universe oscillates at the same exact frequency. So thanks to the atomic clock, we get a time reading ________ to within 1 _________ of a second, and a very _______ measurement of the distance from that satellite. Let's ignore the fact that you're almost definitely on Earth. We now know that you're at a _____ distance from the satellite. In other words, you're somewhere on the surface of a sphere centered around the satellite. Measure your distance from a second satellite and you get another overlapping sphere. Keep doing that, and with just four measurements, and a little correction using Einstein's theory of relativity, you can ________ your location to exactly one point in space. So that's all it takes: a multibillion-dollar network of satellites, oscillating cesium atoms, quantum mechanics, relativity, a __________, and you. No problem.
Solution
- frequency
- powered
- mechanics
- characteristic
- phone
- enter
- distance
- levels
- clock
- quantum
- satellite
- speed
- difference
- precise
- smartphone
- accurate
- swinging
- satellites
- times
- calculate
- equal
- billionth
- crystal
- arbitrary
- invented
- pinpoint
- constrained
- fixed
- constant
- atomic
- signal
- action
- signals
- amount
- concerned
Original Text
How does your smartphone know exactly where you are? The answer lies 12,000 miles over your head in an orbiting satellite that keeps time to the beat of an atomic clock powered by quantum mechanics. Phew. Let's break that down. First of all, why is it so important to know what time it is on a satellite when location is what we're concerned about? The first thing your phone needs to determine is how far it is from a satellite. Each satellite constantly broadcasts radio signals that travel from space to your phone at the speed of light. Your phone records the signal arrival time and uses it to calculate the distance to the satellite using the simple formula, distance = c x time, where c is the speed of light and time is how long the signal traveled. But there's a problem. Light is incredibly fast. If we were only able to calculate time to the nearest second, every location on Earth, and far beyond, would seem to be the same distance from the satellite. So in order to calculate that distance to within a few dozen feet, we need the best clock ever invented. Enter atomic clocks, some of which are so precise that they would not gain or lose a second even if they ran for the next 300 million years. Atomic clocks work because of quantum physics. All clocks must have a constant frequency. In other words, a clock must carry out some repetitive action to mark off equivalent increments of time. Just as a grandfather clock relies on the constant swinging back and forth of a pendulum under gravity, the tick tock of an atomic clock is maintained by the transition between two energy levels of an atom. This is where quantum physics comes into play. Quantum mechanics says that atoms carry energy, but they can't take on just any arbitrary amount. Instead, atomic energy is constrained to a precise set of levels. We call these quanta. As a simple analogy, think about driving a car onto a freeway. As you increase your speed, you would normally continuously go from, say, 20 miles/hour up to 70 miles/hour. Now, if you had a quantum atomic car, you wouldn't accelerate in a linear fashion. Instead, you would instantaneously jump, or transition, from one speed to the next. For an atom, when a transition occurs from one energy level to another, quantum mechanics says that the energy difference is equal to a characteristic frequency, multiplied by a constant, where the change in energy is equal to a number, called Planck's constant, times the frequency. That characteristic frequency is what we need to make our clock. GPS satellites rely on cesium and rubidium atoms as frequency standards. In the case of cesium 133, the characteristic clock frequency is 9,192,631,770 Hz. That's 9 billion cycles per second. That's a really fast clock. No matter how skilled a clockmaker may be, every pendulum, wind-up mechanism and quartz crystal resonates at a slightly different frequency. However, every cesium 133 atom in the universe oscillates at the same exact frequency. So thanks to the atomic clock, we get a time reading accurate to within 1 billionth of a second, and a very precise measurement of the distance from that satellite. Let's ignore the fact that you're almost definitely on Earth. We now know that you're at a fixed distance from the satellite. In other words, you're somewhere on the surface of a sphere centered around the satellite. Measure your distance from a second satellite and you get another overlapping sphere. Keep doing that, and with just four measurements, and a little correction using Einstein's theory of relativity, you can pinpoint your location to exactly one point in space. So that's all it takes: a multibillion-dollar network of satellites, oscillating cesium atoms, quantum mechanics, relativity, a smartphone, and you. No problem.
Frequently Occurring Word Combinations
ngrams of length 2
collocation |
frequency |
quantum mechanics |
3 |
atomic clock |
2 |
quantum physics |
2 |
Important Words
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