SAR Fundamentals/Navigation instruments theory
From PCSAR
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* approx $70 | * approx $70 | ||
- | {{lesson slide||}} | + | {{lesson slide||2 min}} |
- | '''GPS''' | + | Determine experience level of students. |
+ | * Who uses GPS regularly? | ||
+ | * Who is comfortable reading UTM's off a map? | ||
+ | * Recruit more advanced students to assist in illustrating material. | ||
+ | {{lesson slide||3 min}} | ||
+ | '''How a GPS works''' | ||
- | * | + | 3 major components |
+ | * 1. radio receiver | ||
+ | ** compares time for radio signal to arrive from satellites | ||
+ | ** receives information on satellite locations | ||
+ | ** optional WAAS: receives corrections to satellite location, signal distortions | ||
+ | * 2. computer | ||
+ | ** computes where GPS currently is (needs 4 separated satellites) | ||
+ | *** 10-15m accuracy | ||
+ | *** applies corrections: ~ 1m accuracy | ||
+ | ** records where GPS has been | ||
+ | ** allows entry of remote locations | ||
+ | ** calculates distance and direction between points | ||
+ | ** calculate speed/time | ||
+ | ** draw a route on a map | ||
+ | ** place points on map | ||
+ | * 3. magnetic sensor (only some models) | ||
+ | ** determines direction GPS is facing | ||
+ | ** GPS without magnetic sensor tells what direction GPS has moved, but not direction GPS is facing | ||
+ | ** test GPS by turning it. Does the direction arrow change? | ||
- | {{lesson slide||}} | + | {{lesson slide||10 min}} |
- | ''' | + | '''How a GPS fails'' |
- | + | ||
- | + | ||
- | + | radio signal not received from 4 satellites | |
- | * | + | * heavy tree cover |
- | * | + | * blocked view of sky (hills, mountains, building) |
+ | * blocked view of geosynchronous WAAS satellites (32 deg elevation around Pincher Creek) | ||
+ | ** North America only | ||
+ | * satellites not in right positions (below/at horizon, clustered) | ||
+ | * satellites not working/disabled (military selective availability) | ||
+ | * radio interference (jamming; spoofing) | ||
+ | * multipath (reflected) signals[3] | ||
+ | * weather does not affect signal | ||
+ | computer fails | ||
+ | * batteries (-15C) | ||
+ | * temperature (too hot) | ||
+ | * water/condensation (if not sealed) | ||
+ | * electromagnetic interference (industrial sites) | ||
+ | magnetic sensor fails (same as compass) | ||
+ | * metal (belt buckles, cars) | ||
+ | * magnetic fields (power lines) | ||
+ | * magnetic anomalies (far north) | ||
+ | {{lesson slide||4 min}} | ||
+ | '''Alternatives/Aids to GPS''' | ||
+ | * location: dead recogning / distance-bearing / triangulation | ||
+ | * recording: paper | ||
+ | * distance/direction: subtraction & estimation; plot on map | ||
+ | * map (better choice) | ||
+ | * bearing: compass (better choice) | ||
+ | {{lesson slide|7 min 7,6,}} | ||
+ | '''When is a GPS sufficient/help/not helpful''' | ||
+ | discuss examples, compare with other alternatives | ||
+ | |||
+ | determine location when at | ||
+ | * hill top: + | ||
+ | * valley bottom: depends on tightness | ||
+ | * heavy trees: depends on type of trees, wetness | ||
+ | * canyon: - | ||
+ | * south side of a lone hill: + | ||
+ | * north side of a lone hill: poorer -- no WAAS | ||
+ | * downtown city: poor : multipath | ||
+ | * under power lines: + | ||
+ | * heavy fog: + | ||
+ | * blizzard: + | ||
+ | determine direction/distance to | ||
+ | * known UTM: sufficient | ||
+ | * some place you can see: not helpful or only poor with magnetic sensor | ||
+ | * some place you've been: sufficient if you took a waypoint | ||
+ | * a LatLong: sufficient | ||
+ | * a street address: for street GPS | ||
+ | route selection: poor unless street | ||
+ | |||
+ | remembering a UTM: sufficient | ||
+ | |||
+ | {{lesson plan||5 min 5,6}} | ||
+ | '''Significant configuration settings''' | ||
+ | |||
+ | Most GPS's allow you to configure: | ||
+ | * True North vs. Magnetic North | ||
+ | ** use True North | ||
+ | ** GPS's don't generally allow you to set declination to exact same value used on compasses. | ||
+ | * UTM vs. Lat / Long | ||
+ | ** UTM generally used by SAR | ||
+ | * Map Datum: NAD27 vs NAD83/WGS84 | ||
+ | ** measurement of the shape of the Earth | ||
+ | ** NAD - North American Datum | ||
+ | ** WGS - World Geodetic Survey | ||
+ | ** should use same as the topo map being used | ||
+ | ** Pincher SAR maps generally NAD27 | ||
+ | |||
+ | {{lesson plan||9 min}} | ||
+ | '''configure a particular model for local SAR usage''' | ||
+ | |||
+ | ''Handout PCSAR GPS Configuration sheet'' | ||
+ | |||
+ | ''Exercise:'' Students configure their GPS | ||
+ | |||
+ | '''Help students to configure if their particular model not same as PCSAR GPS'' | ||
+ | |||
+ | {{lesson plan||23 min}} | ||
+ | '''Reading a UTM''' | ||
+ | |||
+ | ''Assume students have basic background in UTM'' | ||
+ | |||
+ | * ''Distribute: topo maps'' | ||
+ | * ZEN (Zone Easting Northing) | ||
+ | * long form of numbers | ||
+ | ** read off corner of topo maps | ||
+ | ** northing: number of meters north of the equator | ||
+ | ** easting: number of meters east of imaginary zone line (500km center line) | ||
+ | ** converting to short form | ||
+ | * Read the current/last known UTM | ||
+ | ** last location where GPS was turned on and could see satellites | ||
+ | ** instructions on front of Pincher SAR GPS's | ||
+ | ** determining accuracy | ||
+ | *** Garmin eTrex: on Satellite Page | ||
+ | |||
+ | ''Exercise:'' | ||
+ | * Record last known UTM in long form | ||
+ | * Give last known UTM in short form | ||
+ | * Go outside, record current UTM in long and short form, note accuracy. | ||
+ | * assist students that don't have Pincher SAR GPS | ||
+ | |||
+ | {{lesson plan||10 min}} | ||
+ | '''Manual determination of Distance and Direction''' | ||
+ | * use map | ||
+ | * without map | ||
+ | ** subtract Easting/Northing | ||
+ | ** estimate distance or Pythagorean theorem | ||
+ | ** estimate direction or calculate Tangent | ||
+ | ** or draw scale map | ||
+ | ''Example:'' | ||
+ | * I'm at Zone:12U Easting: 0286623 Northing: 5484642 | ||
+ | * I'm going to:12U Easting: 0287134 Northing: 5484419 | ||
+ | * location is: 511 meters East and 223 meters South | ||
+ | * estimate: ESE 620m | ||
+ | * map/calculation: 129 degrees 661m | ||
+ | |||
+ | {{lesson plan||10 min}} | ||
+ | '''Choosing a GPS''' | ||
+ | Discuss GPS model selection/shopping | ||
+ | * Packaging: hand held, phone, car | ||
+ | * Features: sensitivity, WAAS, map, computer interface | ||
+ | * Brands | ||
+ | * Prices | ||
{{lesson slides end}} | {{lesson slides end}} |
Revision as of 01:53, 30 December 2012
Contents |
Subject
What is this lesson plan about?
This lesson gives the students a theoretical (class room) understanding of the instruments that they may be using in the field to aid navigation.
The instruments covered are:
- compass
- GPS
- altimeter
- stride tally counter
For each instrument, the theory of how it operates is discussed along with how to select an instrument for purchase.
Authors
List who wrote this lesson plan.
- Brett Wuth
Scope
What is included in this lesson, what's not and why.
- SAR Fundamentals Ch.13 "Navigation"
- Basic SAR Skills Manual: Ch.7 "Navigation"
- stride count
Only basic use of a GPS is shown. Advanced features such as waypoints, tracks and maps are left to another lesson beyond the SAR Fundamentals course.
- Waypoints are not an essential skill for using GPS. Students should be recording locations on paper, and should be able to estimate relative direction and distance to a new location.
- This material can be covered in additional material presented by a SAR group outside the SAR Fundamentals course.
Prerequisites
What should students already know/have accomplished before the lesson is presented.
Prior to this lesson, students should have already been introduced to the following concepts:
- direction measured in degrees
- directions measured from True North (this lesson will introduce declination and magnetic north)
Parts of a compass which can be used on a map
- straight edge
- ruler
- rotatable bezel and interior north-south lines
- roamer
- magnifying lens
Specifying a location in UTM
- the three components of a UTM: Zone, Easting, Northing
- map datums: NAD27 vs WGS84
- the 6 digit short form of UTM
elevation
- contour lines
Objectives
At the conclusion of this lesson the participants will be able to:
- explain how a GPS works
- identify purposes for which a GPS is sufficient, a help, not useful
- identify circumstances under which a GPS may fail
- identify the significant configuration options of most GPS models
- identify when to use NAD27 vs. NAD83/WGS84
- configure a particular model for local SAR usage
- read a UTM off a particular model and translate that to and from the UTM notation used with topographic maps.
- determine the UTM of the location where they are at and the accuracy of their reading
- given a destination UTM know what direction and distance to go to get to it
Time Plan
Total Time: 90 minutes
Time | Material
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00:00 3 min |
Introduce topic title Introduce Instructor Present Objectives |
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00:03
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Instruments SAR workers use navigation instruments to make measurements in the field. The measurements are used to calculate your location or that of other things. The four instruments we will discuss:
No one instrument is perfect. Each is better in some circumstances. Each instrument has a different way of failing.
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So far having been using the compass on the map. Can also be used in the field. Because of magnetic needle.
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Magnetic North, Declination The needle of the compass points in the direction of Magnetic North. This is not the same as True North. The difference between True North and Magnetic North is called Declination. It's expressed in degrees and fractions of degrees (minutes). If Magnetic North is to the west of True North, the declination is degrees WEST. Opposite is degrees EAST.
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What direction is Magnetic North? Magnetic North points in the direct of Earth's North Magnetic Pole. It's also somewhat altered by regional geomagnetic features. The North Magnetic Pole isn't the same location as the north pole. North Magnetic Pole is currently (2012) 85.9 deg N 147.0 deg W northwest of of the tip of Ellsmere Island. It moves. About 55 km closer to Russia each year.
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Finding declination Declination changes from year to year. It also changes from area to area. Because North Pole and the North Magnetic Pole appear further apart or closer together depending on where you are located. In our area, declination increases:
Calculation on topo maps is old, not accurate. Ask the person briefing you.
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Compass failures Compasses don't work: when there's magnetic distrubances
attracted to certain metals (iron, nickel, cobalt, alloys like steel)
when the needle doesn't settle
when the needle scrapes the housing
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Choosing a compass Features to look for in compass:
Good compasses:
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Determine experience level of students.
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How a GPS works 3 major components
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'How a GPS fails radio signal not received from 4 satellites
computer fails
magnetic sensor fails (same as compass)
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Alternatives/Aids to GPS
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7 min 7,6,
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When is a GPS sufficient/help/not helpful discuss examples, compare with other alternatives determine location when at
determine direction/distance to
route selection: poor unless street remembering a UTM: sufficient
Significant configuration settings Most GPS's allow you to configure:
configure a particular model for local SAR usage Handout PCSAR GPS Configuration sheet Exercise: Students configure their GPS 'Help students to configure if their particular model not same as PCSAR GPS
Reading a UTM Assume students have basic background in UTM
Exercise:
Manual determination of Distance and Direction
Example:
Choosing a GPS Discuss GPS model selection/shopping
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Aids
What materials are needed or useful in presenting this lesson.
- compasses for students
- 5 Pincher SAR Garmin eTrex GPS's
- 1 Brett Wuth's Garmin eTrex GPS
- 5 copies topo map of locale (82 H/5)
- copy for each student of local street map
- copy for each student of PCSAR Doc-69 GPS - Set-Up and Maintenance
- copy for each student of outside exercise sheet, adapted to locale
- Radios
Question bank
List of questions suitable for an review/exam of this section.
Frequently Asked Questions
What are some of the questions that students typically ask. Include the answers.
- How does global compass work at any latitude?
From http://www.mapworld.co.nz/global.html
In the global compass, this problem has been solved with a structural innovation. The needle and magnet are built as separate units functioning independently from each other, so that the inclination of the magnetic field cannot tilt the needle. The needle can no longer move vertically. It is the compass magnet, separated from the needle, which absorbs the vertical force of the magnetic field. The needle itself is fixed at the lid by means of a double jeweled bearing. The magnet rotates with its jewel bearing on a pin. Such a compass works reliably in all zones of the world. Due to the strong magnet, the needle settles very quickly and stops immediately at the right position, allowing for an extremely accurate reading.
Feedback
When has this lesson been presented. What was the feedback.
License
What can others do with this lesson?
Recommended license below. Fill in the year and the author's name(s):
Copyright © YEAR, Author. This work is licensed under a Creative Commons Attribution-NonCommercial 2.5 Canada License. To view a copy of this license, visit http://creativecommons.org/licenses/by-nc/2.5/ca/ or send a letter to Creative Commons, 559 Nathan Abbott Way, Stanford, California 94305, USA.
Reference Material
If you need to cite sources, do so here.
[1]
Notes
Any additional notes, etc.