Cómo Funciona el GPS 🛰️Qué es el GPS

VirtualBrain

27 Jan 202210:00

Summary

TLDRThis video explains how the Global Positioning System (GPS) works, delving into the use of satellite signals and geometry to calculate precise locations. It covers the complexity of satellite movement, the speed of light, and how even small timing errors can impact location accuracy. The video also discusses how multiple satellite networks, including GPS, GLONASS, and Galileo, work together. Other challenges like signal refraction through the atmosphere, relativistic time dilation, and the role of atomic clocks are explored, showing how advanced mathematics and physics ensure GPS accuracy.

Takeaways

📡 GPS is a satellite-based radio navigation system that calculates positions using signals sent from satellites to devices like phones.
🚀 Satellites move at around 14,000 kilometers per hour, and signals travel at the speed of light, making precise timing crucial.
⏱️ A synchronization error of just one microsecond can result in a location error of nearly 300 meters.
🌍 GPS is part of the broader GNSS (Global Navigation Satellite System), with other systems like GLONASS (Russia), Galileo (EU), and BeiDou (China).
📏 GPS positioning relies on trilateration, using the distance between satellites and the receiver to pinpoint location.
🌐 A minimum of 24 satellites orbit Earth to ensure global coverage, but 31 are operational for robustness and redundancy.
🕰️ GPS requires extremely accurate time measurements, using atomic clocks to minimize errors to within 30 centimeters.
🌪️ Time dilation and atmospheric interference affect GPS signal accuracy, requiring adjustments based on Einstein’s theory of relativity.
📲 Consumer devices like phones lack atomic clocks, so they estimate timing errors using data from multiple satellites and mathematical techniques like least squares.
🔧 Atmospheric layers and signal refraction can distort GPS signals, but mathematical models help correct these delays.

Q & A

What is GPS and how does it work?
-GPS (Global Positioning System) is a satellite-based radio navigation system that allows devices like smartphones to receive data from satellites and calculate their location using geometry. The system can determine a device's position with a precision of 4.9 meters.
What are some challenges that GPS must overcome to function accurately?
-GPS faces challenges such as the high speed of satellites (14,000 km/h), the need for precise synchronization between the satellites and receivers, and the impact of signal delay due to atmospheric layers. Any small errors, like a microsecond misalignment, could result in a location error of nearly 300 meters.
Why are there currently 31 operational GPS satellites if only four are needed to calculate location?
-The 31 satellites provide global coverage and ensure robustness in the system. With satellites positioned in six orbital planes, every point on Earth is guaranteed to have at least four visible satellites at any given time. The extra satellites also provide redundancy in case of signal loss or satellite malfunction.
What is the trilateration method, and how is it used in GPS?
-Trilateration is a mathematical method used to determine a device's position by measuring its distance from at least three satellites. The system calculates the possible intersection points of spheres (in 3D) formed by the satellites and the device, and the correct location is the point where all spheres intersect.
What coordinate system does GPS use, and how does it function?
-GPS uses the World Geodetic System 1984 (WGS 84), where the coordinate origin is the Earth's center of mass. The Z-axis points to the North Pole, the X-axis intersects the Equator and the Greenwich meridian, and the Y-axis is perpendicular to both, forming a right-handed system.
How does the GPS system calculate the distance between a satellite and a receiver?
-The distance is calculated by measuring the travel time of an electromagnetic signal sent by the satellite, which moves at the speed of light. The system measures the time difference between when the signal was sent and when it was received, and uses this to compute the distance.
What role do atomic clocks play in the GPS system?
-Atomic clocks provide highly precise time measurements, essential for calculating distances. Because GPS signals travel at the speed of light, even a microsecond error can lead to a 300-meter error in location. Atomic clocks help minimize this error to within 30 centimeters.
How does Einstein’s theory of relativity affect GPS accuracy?
-Einstein’s theory of relativity predicts that time moves differently for objects in motion or under the influence of gravity. GPS satellites, moving at high speeds and far from Earth’s gravitational pull, experience time dilation. Without compensating for this, there would be a 38.4-microsecond time error each day, which translates to a location error of several kilometers.
How does atmospheric refraction affect GPS signals, and how is it corrected?
-As GPS signals pass through the Earth’s atmosphere, they are refracted, or bent, causing slight deviations in their path and slowing their speed. This affects the signal's travel time, potentially leading to errors. Mathematical models are used to predict and correct these atmospheric delays.
How do smartphones without atomic clocks calculate GPS positions accurately?
-Smartphones lack atomic clocks, so they estimate the time error across signals from multiple satellites. The error is treated as an unknown variable and solved using mathematical techniques like least squares, which minimizes the discrepancies and allows the device to accurately calculate its position.