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DeLorme Earthmate PN-20 GPS Source:

The DeLorme Earthmate PN-20 GPS receiver helps navigate the globe using a web of satellites. The idea of world-wide positioning technology took some time to develop into the system we have today. It was first based on radio navigation systems from WWII. The idea was also propelled further following the Soviet Union's launch of Sputnik in 1957. The first GPS satellite was launched in 1978 by the United States Department of Defense. The Department of Defense developed this technology for military use, and named the program NAVSTAR GPS. However, in 1983 after a Soviet aircraft shot down a civilian plane, President Reagan announced that the NAVSTAR GPS network would be open for public use upon it's completion. The 24th satellite was launched in 1994, and by April 1995 the system was fully operational. There are several other global navigation satellite systems being developed today, including the Russian GLONASS network, the European Galileo positioning system, as well as the Chinese COMPASS navigation system. In 1998, a plan to improve the accuracy and reliability of the NAVSTAR GPS network was announced. In 2004, the A-GPS (Assisted GPS) was introduced to enhance the performance further. The A-GPS came hand in hand with a FCC mandate which required that all cell phones could be tracked using GPS and located by Emergency Call Dispatchers.

The sole application of GPS is not only for the use of the government and cell phone tracking. Presently, GPS is used for countless applications, including military use, mapping and surveying, emergency cell phone and vehicle tracking, as well as personal devices like the DeLorme Earthmate PN-20

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This section should include an introduction of the product and a brief description of group members (i.e. who was responsible for which sections or tasks)

How GPS works

This is a link to a breif video that demonstrates how GPS satellites locate a reciever on the earth.

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Error Correction

Though the theory for the calculation of a point with GPS is sound there are several varibles in the real world that can cause inaccuracies in the readings of GPS data. The clocks in the satellites or the reciever may drift away from “true time”, the thickness of the atmosphere at by the reciever, signals from the satellite bouncing off of buildings or skyscrapers and the like can cause inaccurate readings from GPS equipment. The syncronization of clocks and timing devices between the satellites and recievers is critical to obtaining an accurate reading. If the clocks are even a little off your reciever could be off by a significant distance. The problem that arises here is that no clocks keep time perfectly. After a period of time different clock will show different times from eachother. Atomic clocks are the most precise time measurements that we have but at $50,000-$100,000 each the cost of putting one of those in a reciever instantly puts GPS recievers outside the buget of most people. The solution that was come up with was to install much cheaper quartz clocks in the recievers and program them to reset themselves based on information received from three of four satellites. With this method GPS recievers are able to retain the time accuracy required for an accurate reading without being overly expensive.

The last problem addressed here is the problem of judging the distance. The distance from the reciever to the satellite is based on the signal traveling at the speed of light in a straight line. However that is often not the case. When that signal enters earth’s atmosphere it doesn’t maintain the speed of light but acctually slows down a bit. To add to the confusion, if you are in a city with tall buildings around the signal can bounce off of the buildings before getting to your reciever adding a significant margin of error. To accommodate for this a secondary, checking system was set up called the Differential GPS. Differential GPS works by setting up a stationary reciever antenna on the earth and using that as a check against the satellite. A DGPS reciever knows its own possition one the earth and so it uses measurements from the satellites to calculate inaccuracies in the satellite reading and then provide the correction data to other recievers in the area.

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Public Safety and Disaster Relief using GPS

The Global Positioning System (GPS) provides information that is critical to disaster relief teams and public safety personnel in order to protect life and reduce property loss. GPS has played a vital role in relief efforts for global disasters such as the tsunami that struck in the Indian Ocean region in 2004, Hurricanes Katrina and Rita that wreaked havoc in the Gulf of Mexico in 2005, and the Pakistan-India earthquake in 2005.

Another area of disaster relief that may not be commonly thought of is the management of wildfires. To contain and manage forest fires, aircraft combine GPS with infrared scanners to identify fire boundaries and “hot spots.” Within minutes, fire maps are transmitted to a portable field computer at the firefighters’ camp. Armed with this information, firefighters have a greater chance of winning the battle against the blaze.

GPS is playing an increasingly prominent role in helping scientists to anticipate earthquakes. Using the precise position information provided by GPS, scientists can study how strain builds up slowly over time in an attempt to characterize, and in the future perhaps anticipate, earthquakes.

GPS has given managers a quantum leap forward in efficient operation of their emergency response teams. The ability to effectively identify and view the location of police, fire, rescue, and individual vehicles or boats, and how their location relates to an entire network of transportation systems in a geographic area, has resulted in a whole new way of doing business. Location information provided by GPS, coupled with automation, reduces delay in the dispatch of emergency services.

The FCC now requires that all cell phones be equipped with a GPS device. This helps emergency call dispatchers locate where the call is coming from. With this information, victim's that are unable to give their whereabouts will still be able to be located by emergency services.

The modernization of GPS will further facilitate disaster relief and public safety services. GPS modernization translates to more lives saved and faster recovery for victims of global tragedies.

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  • Deliver disaster relief to areas in a more timely and accurate manner, saving lives and restoring critical infrastructure.
  • Provide position information for mapping of disaster regions where little or no mapping information is available.
  • Enhance capability for flood prediction and monitoring of seismic precursors and events.
  • Provide positional information about individuals with mobile phones and in vehicles in case of emergency.

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Surveying and Mapping with GPS

Using the near pinpoint accuracy provided by the Global Positioning System (GPS) with ground augmentations, highly accurate surveying and mapping results can be rapidly obtained, thereby significantly reducing the amount of equipment and labor hours that are normally required of other conventional surveying and mapping techniques. Today it is possible for a single surveyor to accomplish in one day what used to take weeks with an entire team. GPS is unaffected by rain, wind, or reduced sunlight, and is rapidly being adopted by professional surveyors and mapping personnel throughout the world.

Throughout the world, government agencies, scientific organizations, and commercial operations are using the surveys and maps deriving from GPS for timely decision-making and wiser use of resources. Any organization or agency that requires accurate location information can benefit from the efficiency and productivity provided by the positioning capability of GPS.

Unlike traditional techniques, GPS surveying is not bound by constraints such as line-of-sight visibility between reference stations. Also, the spacing between stations can be increased. The increased flexibility of GPS also permits survey stations to be established at easily accessible sites rather than being confined to hilltops as previously required.

Remote GPS systems may be carried by one person in a backpack, mounted on the roof of an automobile, or fastened atop an all-terrain vehicle to permit rapid and accurate field data collection. With a GPS radio communication link, real-time, continuous centimeter-level accuracy makes possible a productivity level that is virtually unattainable using optical survey instruments.

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  • Provides significant productivity gains over traditional surveying by eliminating many of its inherent limitations, such as the requirement for a line of sight between surveying points.
  • Provides accurate positioning of natural and artificial features that can be used to create maps and models that are used for a wide range of services such as disaster relief and public safety.
  • Gives decision-makers timely and valuable information for wise use of resources.
  • Yields highly accurate surveying results in real-time at the centimeter-level.
  • Allows surveyors to work uninterrupted in periods of poor weather conditions or reduced sunlight.

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Recreational GPS Use

Recreational GPS Use

GPS has eliminated many of the hazards associated with common recreational activities by providing a capability to determine a precise location. GPS receivers have also broadened the scope and enjoyment of outdoor activities by simplifying many of the traditional problems, such as staying on the “correct trail” or returning to the best fishing spot.

Outdoor exploration carries with it many intrinsic dangers, one of the most important of which is the potential for getting lost in unfamiliar or unsafe territory. Hikers, bicyclists, and outdoor adventurers are increasingly relying on GPS instead of traditional paper maps, compasses, or landmarks. Paper maps are often outdated, and compasses and landmarks may not provide the precise location information necessary to avoid venturing into unfamiliar areas. In addition, darkness and adverse weather conditions may also contribute to imprecise navigation results.

GPS technology coupled with electronic mapping has helped to overcome much of the traditional hardships associated with unbounded exploration. GPS handsets allow users to safely traverse trails with the confidence of knowing precisely where they are at all times, as well as how to return to their starting point. One of the benefits is the ability to record and return to waypoints.

Golfers use GPS to measure precise distances within the course and improve their game. Other applications include skiing, as well as recreational aviation and boating.

GPS technology has generated entirely new sports and outdoor activities. An example of this is geocaching, a sport which rolls a pleasurable day’s outing and a treasure hunt into one. Another new sport is geodashing, a cross-country race to a predefined GPS coordinate.

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  • Highly accurate all-weather positioning information using GPS receivers helps outdoor adventurers with safer exploration anywhere in the world.
  • Ability to return to favorite fishing spots, trails, campsites or other locations with precision year after year, despite changing terrain conditions.
  • New and interesting activities (based solely on the capabilities of GPS) are developed every day by outdoor enthusiasts and shared with others.
  • Relatively small, portable, and affordable handsets can be used for multiple types of recreation activities.

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Terrestrial Vehicle use of GPS

It is common today to see GPS receivers built into new vehicles or to see an individual unit installed in older vehicles. By introducing this system, the driver will be provided with navigation, which may be linked to real-time information systems reducing travel time and fuel consumption. Provided that the trip information was programmed prior to leaving, GPS navigation will increase road safety as drivers who are unfamiliar to a region will be able to reach their destination without having to remove their eyes from the road.

Vehicle tracking has been a new feature introduced to industries and to the public. Commercial industries can use GPS to locate a shipment of packages, the speed of the driver, and the estimated time of arrival down to the minute. Law enforcement in Los Angeles are testing a device that deploys a GPS receiver onto a fleeing vehicle to track them instead of entering a potentially high speed and/or fatal pursuit. Public uses can include a parent tracking the location of children driving a tagged vehicle with the additional ability to check where the car stopped and for how long, the maximum speed, and average speed of the vehicle.

The future uses of GPS will undoubtedly grow as the US government is designing the Intelligent Transportation System (ITS). Automakers are using GPS in addition with other technologies to design cars that have automatic driving systems built in, which will be able to drive a vehicle to a set location.


Aviation with GPS

With the introduction of GPS and the numerous advances made in increasing accuracy, aviation has benefited greatly. The GPS system alone provides useful information allowing pilots to fly in more efficient routes in a safe manner. There are two augmentations have provided airports with smoother operation and safety, these are the Wide Area Augmentation System (WAAS) and the Local Area Augmentation System (LAAS).

WAAS is a satellite based augmentation to GPA that covers the entire United States airspace and corrects for errors that occur in standard GPS signals. These signals have an accuracy of 7 meters as opposed to the GPS accuracy of 100 meters and are useful in aiding pilots in landing and enroute. Pilots will be able to plot courses that are more direct because the paths do not require ground surface infrastructure.

LAAS is a system that assists GPS in a specific location, such as an airport runway, and provides much better accuracy on the local level by using ground equipment. If installed at airports, regulators will be able to reduce the distance requirements imposed on aircraft, allowing for greater number of flights. Using the LAAS, a pilot will have the ability to land a plane in conditions of zero visibility, although this has not yet been approved by the Federal Aviation Administration (FAA) for such use.

Utilizing these two augmentations, there are possibilities for shorter flight times, greater capacity, reduced maintenance costs, and safer flights from takeoff gate to landing gate.


Military GPS Use

Along with civilian uses, GPS has multiple military uses. The most common use of GPS within the military is for the guidance of bombs and missiles. The only method of bombing before the development of GPS was to drop a high volume of bombs in order to hit the target. This method was costly in both materials used and especially in civilian collateral damage and casualties. With the use of GPS missiles and bombs can be guided directly onto a target. Modern missiles use multichannel GPS receivers to constantly update its position relative to its target. This ensures the highest level of accuracy possible in order to minimize collateral damages and civilian casualties while accomplishing the mission.

Another use of GPS within the military is in navigation. Personal GPS systems can allow operations to be undertaken during the night while still maintaining a high navigational standard. It can also be used to track a soldier in the event of a rescue mission being required. Also, it can be used on a larger scale as it can provide near instant feedback regarding troop location and deployment. This can be used by officers running an offensive to efficiently coordinate their troops in an attack.


Maritime GPS Use

An area where GPS is rapidly gaining use is at sea. In the shifting tides and currents of the earth’s waterways, it is vital for a ship’s captain to be able to accurately determine his position, bearing, and speed. This is important to ensure that the ship maintains its course and reaches port in the fastest possible manner. Any delays at sea would cost a commercial shipping company large sums of money. GPS is also used to ensure the safety of vessels at sea, and especially as they exit or enter ports. Along with being able to track and avoid other vessels in the area, GPS is used to steer around underwater obstacles. Barrier reefs and other underwater obstacles can be mapped and placed onto GPS systems so that ship captains can successfully steer around these dangerous objects. GPS can also be used to place buoys and other maritime equipment to ensure it is accurately placed.


Disassembly Procedure

  • Document each step to disassemble the product
  • How difficult was each disassembly step?
  • What types of tools were required to perform this step?
  • Include a picture of each disassembly step

After Disassembly

Part Table, including:

  • Part number
  • Part name
  • Number of parts of this type
  • Part material
  • Part manufacturing process
  • Image of the part
  • CAD file for selected parts


  • Document each step to reassemble the product
  • How difficult was each assembly step?
  • What types of tools were required to perform this step?

After Assembly

  • Does it still work?
  • Conclusion remarks


APA Style You must use this format (It's easier than MLA, so don't worry).

Guide to Writing Wiki Code

The beauty about Wiki is that if you don't know the code, you can steal it from someone's page that does. Feel free to click the "edit" links or tabs to view the code for sections or the pages respectively. Be weary about wrecking havoc on another's page. Each page can be rollbacked to a previous verison and your username is linked to all changes. Although you might think it's cool to go through and insert "MIKE RULES" throughout the page, I'm sure Dr. Lewis would not be pleased.

Here's a few tips on writing with Wiki:

This is a bracket "[" "]"

This is a brace "{" "}"

To create a new page/link within Wiki:

  • Double brackets, page name, double brackets
  • Typing in a new page name will automatically create a page, which when clicked, you can then edit.
  • Whatever name you first type in is the name of the page. You can't change page names, only create new pages. Think before you create a new page.
  • Don't worry about slashes or anything, all pages are located in the same directory. If I wanted to create a page called "MAE 277 Template" the code would be ''MAE 277 Template'' Note: Brackets are italicized to prevent creating a new page.

Your table of contents is created automatically.

  • 1,2,3,4 are level 2 sections
  • 1.1, 1.2, 1.3 are level 3 headers

To create headers:

  • Section titles are wrapped with two equal signs ==My favorite header==
  • Bold headers within a section are wrapped with three equal signs ===My not-so-favorite header===

Asterisks indicate bullets. Be sure to put each asterisk on a new line.

  • Here's one
  • Here's two *Here's three, but its not on the next line

Bold text:

  • Start line with "b" in "<>". Be sure to end the line with "/b" in "<>" if you don't want the whole paragraph to be bold.
  • Surround text to be bolded with three " ' " marks on either side. Or highlight the text and click the "B" button on the toolbar.


  • "i" in "<>". Don't forget to end with "/i" in "<>"
  • Highlight the text and click the "I" button in the toolbar (It will put four " ' " on either side).

This is a broken link media file caption

Media tags are indicated by "Media:", images by "Image:" Broken links in red. Case is not important. Use the toolbar to get examples if you're not sure.

Spacing is werid in wiki. Single return does nothing.

Double return (blank line), breaks the line.

Triple return (two blank lines), puts an extra blank line between lines of text.

"br" in "<>" will break lines. They can also be used to separate section headers.

Finally, use the "Show Preview" button on the bottom of the page to see how it looks before saving. It will allow you to catch and edit your errors without having to edit the page again. Just don't forget to save it when you're really done.

This is an example table

See help page for more information on the syntax.

This is the table title
This is Column Header 1 This is Column Header 2 This is Column Header 3
This starts Row 1 Width values (pixels) in header are used to designate the width of the column for the entire table. Text will wrap but it helps to control the layout. Height of the row is determined by the row's largest content A return and single vertical lines separate columns in rows. A double vertical line is necessary if you don't break up the text for cells.
This starts Row 2 "br" in brackets
break lines. Wiki sometimes ignores blank lines.
Some html tags can be used, but not many. Notice the align equals center tag at the beginning of the row. It centers the text in the first two columns, but doesn't work for the third column. I don't know why. Adding the tag again to the beginning of the cell in question will center the text.
This starts Row 3 Image tags are in this format:

Double brackets "[["
Image name
| = Vertical Line

The following order is not important, as long as each is separated by a vertical line:

  • Horizontal position (left, center, right)
  • Thumb (to create clickable thumbnail that links to fullsize image), don't include to make a fullsize
  • Size denoted in pixels (if desired)
  • You can add a caption if there is a thumbnail

Then close with double brackets "]]"

Broken links show up in red.

Here's where you can view any uploaded files

This is thumbnail
Camera disassembly 4.jpg

This is a resized image, not a thumbnail, but notice you can still click on it to get the full size.

This starts Row 4 Notice the repeating code for every row? It's important. A vertical line and a dash indicate the start of a new row. An exclamation point indicates the first column. You can put the entire row onto a single line, but it's easier to read if you break it up. Again, wiki usually ignores new paragraphs. Make sure to end the table correctly (vertical line and closed brace). Not doing so might still display the table, but nothing that comes afterwards.