How GPS Works
Basic components of real-time vehicle monitoring systems are:

• 1. Mobile GPS unit
• 2. Communication networks
• 3. Geographic maps

For the purposes of explanation,  let's elaborate on just real-time GPS vehicle tracking systems. Usually, GPS vehicle tracking systems are easy to install: The sytem consists of a GPS receiver (mostly: 12 channel parallel GPS receiver) and cellular modem which is fastened to the target.  A GPS antenna attaches with a magnet to the underside of the bumper cover and a miniature magnet mount cellular antenna fastens to the frame. Power is supplied by a direct connect to vehicle power or by a field replaceable battery pack. The vehicle monitoring system can be accessed from a PC at your office using a software. The location of the vehicle is displayed on a digital map of your area showing movement as it occurs. GPS tracking solutions can deliver the following information (examples):

• real-time tracking of current location with a view second update rate
• displays where vehicles are now
• shows detailed route history
• displays entire fleet at a glance
• alarm inputs and relay outputs
• built-in motion detector for low power use
• view the historical track of a particular vehicle or fleet
• displays location, date, time, speed and direction
• custom reports show locations driven, mileage and all the stops
• find the closest vehicle to an address or landmark
• remote diagnostics
• “panic button" (alert the operator at the central station that there is a medical emergency and help is required)
• how long the vehicle was parked

   

   

Global Positioning System satellites transmit signals to equipment on the ground. GPS receivers passively receive satellite signals; they do not transmit. GPS receivers require an unobstructed view of the sky, so they are used only outdoors and they often do not perform well within forested areas or near tall buildings. GPS operations depend on a very accurate time reference, which is provided by atomic clocks on board.

Each GPS satellite transmits data that indicates its location and the current time. All GPS satellites synchronize operations so that these repeating signals are transmitted at the same instant. The signals, moving at the speed of light, arrive at a GPS receiver at slightly different times because some satellites are further away than others. The distance to the GPS satellites can be determined by estimating the amount of time it takes for their signals to reach the receiver. When the receiver estimates the distance to at least four GPS satellites, it can calculate its position in three dimensions. 

There are at least 24 operational GPS satellites at all times plus a number of spares.  The satellites, operated by the U.S. Department of Defense, orbit with a period of 12 hours (two orbits per day) at a height of about 11,500 miles traveling at near 2,000mph. Ground stations are used to precisely track each satellite's orbit. 

Determining Position
A GPS receiver "knows" the location of the satellites, because that information is included in satellite transmissions. By estimating how far away a satellite is, the receiver also "knows" it is located somewhere on the surface of an imaginary sphere centered at the satellite. It then determines the sizes of several spheres, one for each satellite. The receiver is located where these spheres intersect.

GPS Accuracy
The accuracy of a position determined with GPS depends on the type of receiver. Most hand-held GPS units have about 10-20 meter accuracy. Other types of receivers use a method called Differential GPS (DGPS) to obtain much higher accuracy. DGPS requires an additional receiver fixed at a known location nearby. Observations made by the stationary receiver are used to correct positions recorded by the roving units, producing an accuracy greater than 1 meter.  When the system was created, timing errors were inserted into GPS transmissions to limit the accuracy of non-military GPS receivers to about 100 meters. This part of GPS operations, called Selective Availability, was eliminated in May 2000.

How Is The Signal Timed?
All GPS satellites have several atomic clocks. The signal that is sent out is a random sequence, each part of which is different from every other, called pseudo-random code. This random sequence is repeated continuously. All GPS receivers know this sequence and repeat it internally. Therefore, satellites and the receivers must be in synch. The receiver picks up the satellite's transmission and compares the incoming signal to its own internal signal. By comparing how much the satellite signal is lagging, the travel time becomes known.

GPS Facts
Here are some other interesting facts about the GPS satellites (also called NAVSTAR, the official U.S. Department of Defense name for GPS):

·         The first GPS satellite was launched in 1978.

·         A full constellation of 24 satellites was achieved in 1994.

·         Each satellite is built to last about 10 years. Replacements are constantly being built and launched  into orbit.

·         A GPS satellite weighs approximately 2,000 pounds and is about 17 feet across with the solar panels extended.

·         Transmitter power is only 50 watts or less.

What's the signal?
GPS satellites transmit two low power radio signals, designated L1 and L2. Civilian GPS uses the L1 frequency of 1575.42 MHz in the UHF band. The signals travel by line of sight, meaning they will pass through clouds, glass and plastic but will not go through most solid objects such as buildings and mountains.

A GPS signal contains three different bits of information — a pseudorandom code, ephemeris data and almanac data. The pseudorandom code is simply an I.D. code that identifies which satellite is transmitting information. You can view this number on your GPS unit's satellite page, as it identifies which satellites it's receiving.

Ephemeris data, which is constantly transmitted by each satellite, contains important information about the status of the satellite (healthy or unhealthy), current date and time. This part of the signal is essential for determining a position.

The almanac data tells the GPS receiver where each GPS satellite should be at any time throughout the day. Each satellite transmits almanac data showing the orbital information for that satellite and for every other satellite in the system.

Sources of GPS signal errors 
Factors that can degrade the GPS signal and thus affect accuracy include the following: 

·      Ionosphere and troposphere delays — The satellite signal slows as it passes through the atmosphere. The GPS system uses a built-in model that calculates an average amount of delay to partially correct for this type of error.

·      Signal multi-path — This occurs when the GPS signal is reflected off objects such as tall buildings or large rock surfaces before it reaches the receiver. This increases the travel time of the signal, thereby causing errors.

·      Receiver clock errors — A receiver's built-in clock is not as accurate as the atomic clocks onboard the GPS satellites. Therefore, it may have very slight timing errors.

·      Orbital errors — Also known as ephemeris errors, these are inaccuracies of the satellite's reported location.

·      Number of satellites visible — The more satellites a GPS receiver can "see," the better the accuracy. Buildings, terrain, electronic interference, or sometimes even dense foliage can block signal reception, causing position errors or possibly no position reading at all. GPS units typically will not work indoors, underwater or underground.

·      Satellite geometry/shading — This refers to the relative position of the satellites at any given time. Ideal satellite geometry exits when the satellites are located at wide angles relative to each other. Poor geometry results when the satellites are located in a line or in a tight grouping.

·      Intentional degradation of the satellite signal — Selective Availability (SA) is an intentional degradation of the signal once imposed by the U.S. Department of Defense. SA was intended to prevent military adversaries from using the highly accurate GPS signals. The government turned off SA in May 2000, which significantly improved the accuracy of civilian GPS receivers.

Satellite Facts
      ·     There are some 2,500 satellites orbiting the earth

·    There are over 8,000 foreign objects orbiting the earth consisting of items like nose cones and panels from old satellites  

To learn more about GPS tracking solutions that fit the goals and requirements of your business, contact Universal Tracking Technologies and speak to one of our knowledgeable technicians today!  We can help you select a GPS unit that meets your needs and standards.