Upload
karlie-stabley
View
224
Download
5
Tags:
Embed Size (px)
Citation preview
1
Land Navigation Overview
Ver. 12162013
2
Course Syllabus
• Section 1: Navigation Devices
• Section 2: Map Basics
• Section 3: Basic Land Navigation
• Section 4: Advanced Land Navigation
3
Section 1: Navigation Devices
Ver. 12162013
4
Section 1: Navigation Devices
Orienteering Compass
http://web.williams.edu/Biology/Faculty_Staff/hwilliams/Orienteering/compass.html
Lensatic Compass
http://www.landnavigation.org/Pages/default.aspx
Smartphone Apps
http://www.androidauthority.com/best-compass-apps-android-103888/
http://www.macworld.com/article/2048982/get-to-know-ios-7-compass.html
GPShttp://www.gps.gov/systems/gps/space
/
Primitive Devices
5
Section 1: Navigation Devices
Survival Needle Compass
http://www.wikihow.com/Make-a-Compass
Primitive Navigation DevicesShadow Stick Sun Compass
http://www.youtube.com/watch?v=jtDdtFUJ4HQ#t=73
What you need:1 Needle1 Piece of cork or green leaf1 Puddle or cup of water1 Magnet
How to make the Compass:Stroke the needle in the same direction, using steady, even strokes. After 50 strokes, the needle will be magnetized.
Stick the needle in the cork or place it on the leaf in the water. The magnetized end will point north.
NOTE: It is possible to get confused on which way is North and South with this compass. Always check your East/West alignment with the sun to confirm.
What you need:1 Tall stick (approximately 2 feet)2 Short sticks (approximately 6 inches)3 Rocks
How to make the Compass:Find an open area that gets a good amount of sun.
Insert the tall stick in the ground & place a rock at the tip of the shadow.
Wait 15 minutes, and place the second rock at the tip of the shadow. Wait another 15 minutes, and place the third rock at the tip of the shadow.
Using the short stick, align it against the rocks. This is your East- West line (East is the first rock you put down, West is the last rock)
Use the second short stick to create a North-South line by placing across the East West line.
6
Section 1: Navigation DevicesPros and Cons by Type
Lensatic CompassBest for working with maps AND overland navigation.
Orienteering CompassGood for working with maps, but not suited for overland navigation.
Global Positioning SystemThe most precise navigation device, but subject to solar, environmental, or human interference.
Smartphone Apps Dependent on cell network coverage, high battery drain on devices, needs Wi-Fi for accuracy.
Liquid Filled CompassesLiquid filled compasses are best (less prone to small jittering). Needs extra protection from damage.
Tritium & Life SpanTritium can be dangerous if your compass breaks, and eventually it will no longer glow without a “recharge” of bright concentrated light
While tritium has several different experimentally determined values of its half-life (National Institute of Standards and Technology) lists 4,500±8 days (approximately 12.32 years)
Survival Needle & Shadow Stick Sun CompassesNot recommended for anything more than general cardinal directions.
7
Section 1: Navigation DevicesSecuring Your Navigation Device
• Tie down your device using a Bowline knot– Cut a length of cord approximately 3 feet long– Tie Bowline knots on both ends of the cord– Secure one end to your device by feeding the line through the loop– Secure the other end to your belt by feeding the line through the loop
• Securing your device to a pouch– Cut a length of cord approximately 3 feet long– Tie a Bowline knot in one end of the cord– Secure one end to your device by feeding the line through the loop– Run the untied end through the drain hole of the pouch– On the other side of the drain hole, knot the cord several times with basic
knots & pull tight
Remember the Bowline:The “rabbit” method
1. The rabbit comes out of the hole2. The rabbit goes around the tree3. The rabbit returns to his hole
1 2 3
YouTube Bowline Demonstrationhttps://www.youtube.com/watch?v=Q9NqGd7464U
8
Section 1:Navigation Devices
Paint Sighting Wire and Scale with a white paint
marker for better visibility
5 minute maintenance to improve your Lensatic compass (non-liquid type)
http://www.youtube.com/watch?v=yMzTZAobO2A
Lensatic Compass Tune Up
9
Section 2: Map Basics
Ver. 12162013
10
Section 2: Map Basics• How OLD is your map?
– Weather, time, and human interference will reduce accuracy
• Weather Protection– DIY options for water RESISTANCE http://www.amazon.com/Duck-1115496-Laminate-Adhesive-12-Inch/dp/B002AS9NC6 – Professional lamination is best, but will be expensive depending on map size– Waterproof map storage options https://www.google.com/#q=waterproof+map+storage
• Understanding Map Scale– Map scales in common use for topographic maps are 1:62,500 (15 minute quadrangle), 1:100,000 (one degree sheet) and 1:
250,000 (2° sheet)– The smaller the ratio is between distances on the map and distances in the real world, the smaller the scale of the map is
said to be. In other words, a map with a scale of 1:250,000 is a smaller scale map than a 1:24,000 scale map, but it covers a larger real-world area.
11
Section 2: Map BasicsOrienting your Map with a Compass
http://www.compassdude.com/compass-map-orienting.shtml
1. Place the compass on the map, aligning the scale to the North/South line of the map.
2. Rotate both the map and compass until the needle indicates North.
3. Using the scale as a straightedge, align the compass from your current location to your intended destination to determine the azimuth in degrees.
Reading a Topographic Maphttp://www.artofmanliness.com/2012/06/27/how-to-read-a-topographic-map
/
Lines indicate elevation on a topographic map (see the map scale for actual height).
The closer the lines, the steeper the elevation between them.
The farther apart the lines are, the calmer the elevation between them.
12
Section 2: Map BasicsDeclination: True North vs. Magnetic North
Declination is the difference in degrees between True North and Magnetic North
Go to the NOAA Website:http://www.ngdc.noaa.gov/geomag-web/#declination
1
2
Select your Map Area:Enter the desired Zip Code in the “Search” box and click the “Get Location” button
3
Calculate the Declination:The Latitude and Longitude fields will now populate. Select “HTML” in the Result section , then click the “Calculate button.
Use the “PDF” option if you wish to print the graphic.
Interpreting the Information:The declination factor is shown in the highlight.
How to Interpret the Graphic and Data:The graphic shows that the declination is 14 degrees West (the Magnetic North compass rose is angled to the left of the imaginary North/South line of the map [True North is straight up on the map]).
This means we need to ADD 14 degrees to Magnetic North to achieve True North when navigating.
Magnetic Declination changes over time!! Confirm it at least once per year.
NOTE: If the MN graphic was inclined 14 degrees to the right, we would then subtract our declination factor.
4
13
Section 2: Map BasicsUsing the USGS Website to Download Topo Maps
Go to the Website:http://store.usgs.gov/b2c_usgs/usgs/maplocator/%28xcm=r3standardpitrex_prd&layout=6_1_61_48&uiarea=2&ctype=areaDetails&carea=%24ROOT%29/.do
1
Select your Map Area:Enter the desired Zip Code in the “Search” box and click the “Go” button
2
3
Activate Map Options:Left click on the map’s red marker
4
Download the Map:Select the version desired (be aware of the file’s “size” and “date” information, then click the file size under then “Download” icon to download the map. The map will be compressed (zipped).
5
Printing the Map:These are full size digital images, so they won’t fit on one normal 8.5” x 11” page. It is recommended that you take the file to a printing supply store (Kinkos, OfficeMax, etc) for printing.
14
Section 3: Basic Land Navigation
Ver. 12162013
15
Section 3: Basic Land Navigationhttp://www.shtfblog.com/shooting-an-azimuth-with-your-lensatic-compass/
Shooting an Azimuth
1. Orient your map and determine your direction of travel azimuth in degrees.
2. Placing your thumb in the thumb loop, hold the compass as shown in fig 1.
3. Turn your body to align the compass to your direction of travel azimuth (fig 2).
4. Look through the Sighting Slot and Sighting Wire to find a visible landmark along your azimuth (fig 3).
1
2
3
Be aware of metal interference to the compass!Gear, clothing, hats, etc.
16
Section 3: Basic Land Navigation• Navigation Methods
– Dead Reckoning (straight line to destination)– Terrain Association (navigation based on matching terrain features within sight to a map)
• Terrain Analysis of your Route– What is in the way between you and the destination?
• Which is the smartest way?– Time, Terrain, Weather, Human Factors
17
Section 3: Basic Land NavigationMeasuring Distance on Foot
Determining you Pace Count http://www.backcountryattitude.com/pacing.html
Find a level 100 yard (300 foot) course, like high school football field. Bring a notebook and pen.
1. Normal Cadence:Walk from one goal post to the other at a normal pace, counting how many times your left foot hits the ground. Record the number.
2. Fast Cadence:Walk from one goalpost to the other at a fast pace, counting how many times your left foot hits the ground. Record the number.
3. Slow Cadence:Walk from one goalpost to the other at a half-step pace, counting how many times your left foot hits the ground. Record the number.
By doing this three times at different paces, you can get a rough idea of how far you are moving on normal (flat) terrain, fast (paved) terrain, and slow (rough or uphill) terrain.
Calculate your pace by dividing the length of your course by the amount of paces it took to travel it. So if your course was 300 feet and you counted 50 paces, then that equals a 6 foot pace.
Remember, your pace count will change depending on your terrain! Using this methodology will give you a better idea of
how far you have walked.
Pace Cordhttp
://www.instructables.com/id/Army-Ranger-Beads/
Pace-counting beads are a great way to measure distances travelled by foot. A set of ranger beads is merely a lanyard with
two sets of beads; the bottom section has nine and the top section has five. The
beads are moved at various distances to count your total distance walked.
For every 100 meters the user walks, one of the lower beads are pulled down.
When the ninth of the lower beads are pulled, the user has walked 900 meters. The next time the user has walked 100
more meters, one of the upper beads are pulled down, and all the lower beads are
pulled back up.
18
Section 4: Advanced Land Navigation
Ver. 12162013
19
Section 4: Advanced Land Navigation
• Intersection– Intersection is the location of an unknown point on a map
• Resection– Resection is how to determine your location on the map from two or more known points
• Modified Resection– Modified resection is the method of locating your position on the map while walking on/near
a known linear ground feature, such as a road, canal, or stream
(all three methods in one video)http://www.youtube.com/watch?v=oiDlpAt4Tao
20
Section 4a: Intersection• Intersection
– Intersection is used to locate a visible but unplotted location on a map1. Shoot an Azimuth to the Unknown Location [?] from a Known Point [KP1] on the map2. Record the Azimuth3. Convert the Azimuth to Grid North by adding or subtracting the declination4. Move to a second Known Point [KP2] on the map5. Repeat steps 2 and 3 above6. Plot the intersection on the map. This is the Unknown Location’s position on the map.
SCENARIO: We need to determine the exact location of an encampment of strangers near our
land on the map. We can see them from two observation points and will work together to plot their position on the map.
21
Section 4a: IntersectionIntersection Demonstration
KP1
KP2
GRID
NORTH
Note: Please view in Slideshow Mode for click animation
Click 1:KP1 Azimuth to ? = 340° MagneticAdd Declination Factor (14°)
? is 354° Grid Azimuth from KP1
Click 2:KP2 Azimuth to ? = 300° MagneticAdd Declination Factor (14°)
? is 314° Grid Azimuth from KP2
Click 3:Draw lines on map using solutions above to determine location of ?
22
Section 4b: Resection• Resection
– Resection is how to determine your location on the map from two or more known points
1. Shoot an Azimuth to the first known point on the map2. Record the Azimuth3. Convert the Azimuth to Grid North by adding or subtracting the declination4. Add 180° to convert to azimuth to a BACK azimuth5. Shoot an Azimuth to the second known point on the map6. Repeat steps 2, 3, and 4 above7. Plot the intersection on the map. This is your current location.
SCENARIO: We need to check our position on the map to confirm our terrain association and
pace count.
We can see two distinct landmarks and will use them to plot our correct position on the map.
23
Section 4b: ResectionResection Demonstration
KP1
KP2
GRID
NORTH
Note: Please view in Slideshow Mode for click animation
Click 1:Azimuth to KP1 = 160° MagneticAdd Declination Factor (14°)=174°Add 180° to create Back Azimuth
354° from KP1
Click 2:Azimuth to KP2 = 110° MagneticAdd Declination Factor (14°)=124°Add 180° to create Back Azimuth
304° from KP2
Click 3:Draw lines on map using solutions above to determine YOUR location
YOU
24
Section 4c: Modified Resection• Modified Resection
– Modified resection is the method of locating your position on the map when you are located on a linear feature on the ground, such as a road, canal, or stream
1. Shoot an Azimuth to a known terrain feature2. Record the Azimuth3. Convert the Azimuth to Grid North by adding or subtracting the declination4. Add 180° to convert to azimuth to a BACK azimuth5. Plot the intersection on the map. This is your current location.
SCENARIO: We are walking along Flanders Road and need to check our position on the map.
25
Section 4c: Modified ResectionModified Resection Demonstration
Note: Please view in Slideshow Mode for click animation
Azimuth to Old Church = 320° MagneticAdd Declination Factor (14°) = 334°Add 180° to create Back Azimuth = 514°Since there are only 360° in a circle, we need to
subtract 360° from 514°!We are 154° from Old Church
Draw lines on map using solutions above to determine YOUR location
Click 1Click 2
Old Church
YOU
GRID
NORTH
26
Calculation Cheat Sheet
IntersectionLocate a visible but unplotted location
1.1st Azimuth to Target:______2.+/- Local Declination:______3.Grid Azimuth to Target:____
4.2nd Azimuth to Target:_____5.+/- Local Declination:______6.Grid Azimuth to Target:_____
Orient map and mark Grid Azimuths to intersect on the map.
ResectionDetermine your location on the map
1.Azimuth to Known Point 1:______2.+/- Local Declination:______3.Minus 180° for Back Azimuth4.Grid Azimuth from KP1:_____
Grid Azimuth more than 360°? Subtract 360°.
5.Azimuth to Known Point 2:______6.+/- Local Declination:______7.Minus 180° for Back Azimuth8.Grid Azimuth from KP2:____
Grid Azimuth more than 360°? Subtract 360°.
Orient map and mark Grid Azimuths to intersect on the map.
Modified ResectionDetermine your location while on a liner
terrain feature
1.Azimuth to Target:______2.+/- Local Declination:______3.Minus 180° for Back Azimuth4.Grid Azimuth from Target:____
Grid Azimuth more than 360°? Subtract 360°.
Orient map and mark Grid Azimuth to intersect the liner terrain feature.
?
?
27
Closing Takeaways• Compass navigation is rudimentary compared to GPS. EXPECT it to be
inaccurate compared to your experience with GPS!• ALWAYS take the time to orient yourself to the terrain BEFORE you begin
your navigation movement. Know where major terrain features should be in relation to your own body.
• All compasses are affected by metal. Hold them away from your body and don’t take readings from them near metal objects.
• The longer the distance that you navigate, the more pronounced minor errors will be in finding a precise destination.
• Keep checking your progress every hour through Resection or Modified Resection.
• Keeping a pace count is HARD! Make sure you focus your mind on the task and don’t allow it to wander.
• MAKE SURE YOU PROTECT YOUR MAPS AND YOUR COMPASS!!!!