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absolute georeference
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The referencing in space of the location
of a point using a predefined coordinate system such as a national
grid or latitude/longitude.2
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absolute
positioning
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This
is the mode in which a position is determined, using a single receiver,
with respect to a well-defined coordinate system, typically a Geocentric
system (i.e. a system whose point of origin coincides with the centre
of mass of the earth). Also referred to as 'point positioning',
or 'single receiver positioning'. 6 |
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accuracy
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Conforming
to a recognizable standard. If applied to paper maps or map databases,
degree of conformity with a standard or acceptable value.1
The statistical meaning of accuracy is the degree with which an
estimated mean differs from the true mean.
2 |
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algorithm
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A
step by step procedure for solving a mathematical problem.1 |
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almanac
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An almanac is a library
of coarse satellite orbital data used to calculate satellite position,
rise time, elevation and azimuth. 7 |
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ambiguity
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The unknown integer number of cycles of the reconstructed carrier
phase contained in an unbroken set of measurements from a single
satellite pass at a single receiver. 7
Carrier phase measurements can only
be made in relation to a cycle or wavelength of the L1
or L2 carrier waves because it
is impossible to discriminate different carrier cycles (they are
all "sine waves" if one ignores the modulated messages
and PRN codes). Integrated carrier phase measurements may be made
by those receivers intended for carrier phase-based positioning.
In this case the change in receiver-satellite distance can be
measured by counting the number of whole wavelengths since initial
signal lock-on and adding the instantaneous fractional phase measurement.
However, such a measurement is a biased range or distance measurement
because the initial number of whole (integer) wavelengths in the
receiver-satellite distance is unknown. This unknown value is
referred to as the "ambiguity". It is different for
the different satellites, and different for the L1 and L2 measurements.
It is, however, a constant if signal tracking continues uninterrupted
through an observation session. If there is signal blockage, then
a "cycle slip" occurs, causing the new ambiguity after
the cycle slip to be different from the value before. Cycle slip
repair therefore restores the continuity of carrier cycle counts
and ensures that there is only one ambiguity for each satellite-receiver
pair. 6
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ambiguity
resolution
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If the initial integer ambiguity
value for each satellite-receiver pair could be determined, then
the ambiguous integrated carrier phase measurement can be corrected
to create an unambiguous, but very precise (millimetre observation
accuracy), receiver-satellite distance measurement. A solution using
the corrected carrier phase observations is known as an "ambiguity-fixed"
or "bias-fixed" solution. The mathematical process or
algorithm for determining the value for the ambiguities is Ambiguity
Resolution. Tremendous progress has been made in AR techniques,
making today's carrier phase-based GPS systems very efficient by
cutting down the length of observation data needed (resulting in
so-called "rapid static surveying" techniques) and even
allowing this process to occur while the receiver is itself in motion
(in so-called "on-the-fly" AR techniques). (In practice,
the AR process and the ambiguity-fixed solutions are carried out
on the double-differenced carrier phase observables, not on the
one-way satellite-receiver measurements.) 6 |
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antenna
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That part of the GPS
receiver hardware which receives (and sometimes amplifies) the incoming
L-Band signal. Antennas come in all shapes and sizes, but most these
days use so-called "microstrip" or "patch" antenna
elements. The geodetic antennas, on the other hand, may use a "choke-ring"
to mitigate any multipath signals. 6 |
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antenna splitter
|
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An attachment which can
be used to split the antenna signal into two, so that it may be
fed to two GPS receivers. Such a configuration forms the basis of
a Zero Baseline test. 6 |
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anti-spoofing (AS)
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Encrypting the P-Code
(to form the Y-code). 7
Anti-spoofing i s a policy of the
U.S. Department of Defense by which the P-Code
is encrypted (by the additional modulation of a so-called W-Code
to generate a new Y-Code), to protect the militarily important
P-Code signals from being "spoofed" through the transmission
of false GPS signals by an adversary during times of war. Hence
civilian GPS receivers are unable to make direct P-Code pseudo-range
measurements and must use proprietary (indirect) signal tracking
techniques to make measurements on the L2
carrier wave (for both pseudo-range and carrier phase). All dual-frequency
instrumentation must therefore overcome AS using these special
signal tracking and measurement techniques.6
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anywhere fix
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The ability of a receiver
to start position calculations without being given an approximate
location and approximate time. |
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aspect
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A position facing a particular
direction. Usually referred to in compass directions such as degrees.1 |
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attribute
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A characteristic which describes
a feature. Attributes can be thought of as questions which are asked
about the Feature. Typically associated with geospatial data gathering
for inclusion within Geographic Information Systems (GIS). 6 |
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Australian Height
Datum (AHD)
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Established in 1971 as a national level
datum based on the average mean sea level around the Australian
coastline.
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AUSLIG
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Australian Surveying and Land Information
Group
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Australian Map
Grid (AMG)
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Equivalent to the Universal Transverse Mercator
(UTM) map projection. AMG is broken up into several zones, which
span six degrees of longitude, in order to minimise scale disctortions
in the map projection. Coordinates in each zone are expressed
in eastings and northings.
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availability
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The number of
hours per day that a particular location has sufficient satellites
(above the specified elevation angle, and perhaps less than some
specified PDOP value) to make a GPS position determination possible.
6
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azimuth
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a horizontal
angle measured clockwise from a direction such as North
7 |
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b
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bandwidth
|
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The range of frequencies
in a signal. |
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baseline
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The length of the three-dimensional
vector between a pair of stations for which simultaneous GPS data
has been collected and processed with differential techniques.
7
A baseline consists of a pair of stations
for which simultaneous GPS data have been collected. Mathematically
expressed as a vector of coordinate differences between the two
stations, or an expression of the coordinates of one station with
respect to the other (whose coordinates are assumed known, and
is typically referred to as a "Base" or "Reference"
Station). 6
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base station
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Also called a Reference
Station. In GPS navigation, this is a receiver that is set up on
a known location specifically to collect data for differentially
correcting data files of another receiver (which may be referred
to as the "mobile" or "rover" receiver). In
the case of pseudo-range-based Differential GPS (DGPS) the base
station calculates the error for each satellite and, through differential
correction, improves the accuracy of GPS positions collected at
unknown locations by another (roving) GPS receiver. For GPS Surveying
techniques, the receiver data from the base station is combined
with the data from the other receiver to form double-differenced
observations, from which the baseline vector is determined.
6 |
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bearing
|
|
Term used in navigation to decribe the angle
between a reference direction (e.g. geograohic north, magnetic
north, grid north) and the trajectory. 7
Also referred to as the Azimuth. The
compass direction from a position to a destination. The "north"
direction is "zero bearing", and the angle is measured
clockwise through 360°. May be referred to a number of "north"
directions, including magnetic north, (projection) grid north,
or geographic north. 6
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bias
|
|
All GPS measurements
are affected by biases and errors. Their combined magnitudes will
affect the accuracy of the positioning results (they will bias the
position or baseline solution). Biases may be defined as being those
systematic errors that cause the true measurements to be different
from observed measurements by a "constant, predictable or systematic
amount", such as, for example, all distances being measured
too short, or too long. Biases must somehow be accounted for in
the measurement model used for data processing if high accuracy
is sought. There are several sources of biases with varying characteristics,
such as magnitude, periodicity, satellite or receiver dependency,
etc. Biases may have physical bases, such as the atmosphere effects
on signal propagation or ambiguities in the carrier phase measurements,
but may also enter at the data processing stage through imperfect
knowledge of constants, for example any "fixed" parameters
such as the satellite ephemeris information, station coordinates,
velocity of light, antenna height errors, etc. Random errors will
not bias a solution. However, outlier measurements, or measurements
significantly affected by multipath disturbance (which may be considered
a transient, unmodelled bias), will bias a solution if the proportion
of affected measurements is relatively high compared to the number
of unaffected measurements. For this reason, long period static
GPS Surveying is more accurate (less likely to be biased) than "rapid
static surveying" or kinematic (single-epoch) positioning.
6 |
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binary biphase modulation
|
|
Phase changes of either 0° or 180°
(to represent binary 0 or 1, respectively) on a constant frequency
carrier. These can be modelled by
y = A cos (wt + p)
where the amplitude function A
is a sequence of +1 and -1 values (to represent 0° and 180°
phase changes respectively). GPS signals are biphase modulated.
7
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Binary Shift-Key (BSK)
Modulation
|
|
BSK is a modulation
technique by which a binary message, such the Navigation Message
or the PRN codes (consisting of 0's and 1's), is imprinted on the
carrier wave. Unlike Amplitude Modulation (AM) and Frequency Modulation
(FM), BSK Modulation does not alter the signal level (the "amplitude")
or the carrier wavelength (the "frequency"). At a change
in value of the message from 0 or 1, or from 1 to 0, the carrier
wave is reversed (the phase is "flipped" by 180°).
All reversals take place at the zero-crossings of the carrier (sine)
wave (i.e., where the phase is zero). 6 |
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c
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|
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|
The Coarse/Acqusition code modulated on
the GPS L1
signal. This code is a sequence of 1023 pseudorandom binary biphase
modulations on the GPS carrier at a chipping rate of 1.023 MHz,
thus having a code repetition period of one millisecond. 7
The standard (Clear/Acquisition) GPS
PRN code, also known as the Civilian Code or S-Code. Only modulated
on the L1 carrier. Used by the GPS receiver to acquire and decode
the L1 satellite signal, and from which the L1 pseudo-range measurement
is made. 6
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cadastral map
|
|
A map showing the precise boundaries
and size of land parcels.
|
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cadastre
|
|
A record of interests in land, including
both the nature and extent of interests. Usually this means maps
and other descriptions of land parcels as well as the identification
of who owns certain legal rights to the land. Cadastral information
often includes other descriptive information about land parcels.1
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carrier
|
|
A radio wave having at
least one characteristic (e.g., frequency, amplitude, phase) that
can be varied from a known reference value by modulation. In the
case of GPS there are two transmitted carrier waves: (a)
L1 at 1575.42MHz, (b)
L2 at 1227.60MHz, modulated by
the Navigation Message (both L1 and L2), the P-Code
(both L1 and L2) and the C/A-Code (L1). 6 |
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carrier frequency
|
|
The frequency of the
unmodulated frndamental output of a radio transmitter. The GPS L1
carrier frequency is 1575.42 MHz, the GPS L2
carrier frequecny is 1227.60 MHz. 7 |
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carrier phase
|
|
GPS measurements made
on the L1 or L2
carrier signal. May refer to the fractional part of the L1 or L2
carrier wavelength (approximately 19cm for L1, 24cm for L2), expressed
in units of metres, cycles, fraction of a wavelength or angle. (One
cycle of L1 is equivalent to one wavelength, and similarly for L2.)
In carrier phase-based positioning, such as employed in GPS Surveying
techniques, carrier phase may also refer to the accumulated or integrated
measurement which consists of the fractional part plus the whole
number of wavelengths (or cycles) since signal lock-on. 6 |
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cartesian
coordinate system
|
|
A system or two or three mutually
perpendicular axes along which any point can be precisely located
with reference to any other point, often referred to as x, y and
z coordinates. Relative measure of distance, area and direction
are constant throughout the system. 1
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class of survey
|
|
Class of survey is a means
of categorising the internal quality, or precision of a survey.
The number of categories, the notation applied, and the accuracy
tolerances defining the transition from one class to another are
defined by individual nations. Typically they are based on traditional
geodetic surveying categories, supplemented by several extra categories
of higher precision applicable to GPS Surveying and GPS Geodesy
techniques, and may be different for horizontal surveys and vertical
surveys. The attachment of a particular Class "label"
(e.g. A, B, etc.) to a survey, comprising a few or many points within
a "network", carried out using GPS or any other technique,
is performed as part of the process of "network adjustment"
in which the relative error ellipses (in the horizontal case) between
coordinated stations are computed and compared with the accuracy
standards that must be met for various categories of Class. See
Minimally Constrained. 6 |
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clock bias
|
|
The difference between the
receiver or satellite clock's indicated time and a well-defined
time scale reference such as UTC (Coordinated Universal Time), TAI
(International Atomic Time) or GPST (GPS Time). 6 |
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clock offset
|
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constant difference in the
time reading of two clocks. 7
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coarse acquisition (C/A)
|
|
See also C/A-Code.
A spread spectrum direct sequence code that is used primarily by
commercial GPS receivers to determine the pseudo-range to a transmitting
GPS satellite, modulated on the L1
carrier. 6 |
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code phase
|
|
GPS measurements based on
the C/A-Code. The term is sometimes
restricted to the C/A- or P-Code
pseudo-range measurement when expressed in units of cycles. 6 |
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constellation
|
|
Refers to either the specific
set of satellites used in calculating a position, or all the satellites
visible to a GPS receiver at one time, or the entire ensemble of
GPS satellites comprising the Space Segment. 6 |
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contour
|
|
A line connecting points of equal
value (e.g. elevation), often in reference to a horizontal datum
such as mean sea level.1
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control point
|
|
Also called a Control Station
or Geodetic Control Station. A monumented point to which coordinates
have been assigned by the use of terrestrial or satellite surveying
techniques. The coordinates may be expressed in terms of a satellite
reference coordinate system (such as with respect to WGS84, or to
ITRS), or a local geodetic datum. 6 |
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control segment
|
|
A world-wide network of GPS monitoring
and upload telemetry stations operated by, or on behalf of, the
US Department of Defense. The tracking data is used by the Master
Control Station at Colorado Springs to calculate the satellites'
positions (or "broadcast ephemerides") and their clock
biases. These are formatted into the Navigation Message which is
uploaded on a daily (perhaps more frequently) basis by the Control
Segment stations. 6 |
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coordinate
|
|
The position of a point n space with
respect to a Cartesian coordinate system (x, y and/or z values).
In a GIS, a coordinate often represents locations on the earth’s
surface relative to other locations.1
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correlator
|
|
The GPS receiver "software"
or electronic means, implemented in some fashion (either analogue
or digital) within a Tracking Channel, used to shift or compare
the incoming signal with an internally generated signal. This operation
is performed on the PRN codes, but may be used for more "exotic"
mixed signals in the case of L2
measurements, where under the policy of Anti-Spoofing (AS) the L2
PRN code is not known. Correlator design may be influenced such
that it is optimised for accuracy, mitigation of multipath, acquisition
of signal under foliage, etc. 6 |
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cutoff angle
|
|
The minimum acceptable satellite elevation
angle (above the horizon) to avoid blockage of line-of-sight,
multipath errors or too high Tropospheric or Ionospheric Delay
values. May be preset in the receiver, or applied during data
post-processing. For navigation receivers may be set as low as
5°, while for GPS Surveying typically a cutoff angle of 15°
is used. 6
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cycle slip
|
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A discontinuity of an integer
number of cycles in the measured (integrated) carrier phase resulting
from a temporary loss-of-lock in the carrier tracking loop of a
GPS receiver. This corrupts the carrier phase measurement, causing
the unknown Ambiguity value to be different after the cycle slip
compared with its value before the slip. It must be "repaired"
(the unknown number of "missing" cycles determined and
the carrier observation subsequent to the cycle slip all corrected
by this amount) before the phase data is processed in double-differenced
observables for GPS Surveying techniques. 6 |
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coordinate system
|
|
A systems used to measure horizontal
and vertical distances on a plan metric map. In a GIS, it is the
system whose units and characteristics are defined by a map projection.
A common coordinate systems is used to spatially register geographic
data for the same area.1
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d
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data message
|
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Also known as the 'navigation
message'. A 1500 bit message modulated on the L1
and L2 GPS signal, which contains
the satellite's location (or ephemeris), clock (bias) correction
parameters, constellation almanac information and satellite health.
6 |
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datalogger
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Also known as a Data Recorder.
A handheld, lightweight data entry computer. It can be used to store
additional data obtained by a GPS receiver, such as Attribute information
on a Feature whose coordinates are captured for a GIS project.
6 |
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datum
|
|
Refers to a reference point from which other
points in a survey are measured from. A datum may be a known point
within an existing survey grid or it may be any arbitrary point.
A datum is a means by which coordinates determined by any means
may be related to a well-defined Reference Frame. The Reference
Frame may be visualised as a 3-D Cartesian coordinate system consisting,
as a minimum, of information concerning the origin of the axes,
and the directions of two principal axes fixed to the earth. The
Reference Frame may be globally applicable, such as WGS84 or ITRF,
in which case it is "geocentric" (having its origin
at the earth's centre of mass), or be locally applicable as in
the case of traditional national geodetic frames such as the Australian
Geodetic Datum. In any case, the Datum may be considered synonymous
to the Reference Frame, or be restricted to refer to the set of
coordinates of geodetic stations or benchmarks which provide the
physical realisation of the Reference Frame. A satellite-defined
Datum such as WGS84 may, in addition, be realised by the time-varying
coordinates of the satellites themselves (the Ephemerides). Finally,
the Datum may be defined only in the horizontal sense or for the
vertical component. An example of a Horizontal Datum is a Reference
Ellipsoid (located and oriented in such a way as to be compatible
to the Reference Frame to which it is attached), upon which coordinate
information is expressed in terms of Latitude and Longitude. (WGS84
has a Reference Ellipsoid associated with it.) A Vertical Datum
may be defined by a local realisation of Mean Sea Level, or as
height above the Reference Ellipsoid. 6
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DEM
|
|
Digital elevation model. A quantitative
model of a topographic surface in digital form. Also known as
a ’digital terrain model’ (DTM). The resolution, or the distance
between adjacent grid points, is a critical parameter.
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differential GPS (DGPS)
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Differential or relative GPS is based
on the idea that errors in the position at one location are similar
to those for all locations within a given (local) area. It requires
the use of two or more receivers, where one receiver is located
at a precisely known point and, as it processes information from
the satellites, is able to compute a position. This is compared
with the known position for that point and any discrepancies are
assumed to be a combination of atmospheric, satellite and receiver
errors. These errors can then be applied to all receivers within
a local area. The term differential GPS or DGPS generally refers
to receivers which use code information for positioning. Depending
on the method whereby the differential corrections are generated,
the accuracies of these receivers can be improved from 15-20m
to around 1-5m.
A technique to improve GPS accuracy
that uses pseudo-range errors measured at a known Base Station
location to improve the measurements made by other GPS receivers
within the same general geographic area. It may be implemented
in real-time through the provision of a communication link between
the GPS receivers, transmitting the correction information in
the industry-standard RTCM format, or various proprietary formats.
May be implemented in single Base Station mode, in the so-called
Local Area DGPS (LADGPS), or using a network of Base Stations,
as in the Wide Area DGPS (WADGPS) implementation. 6
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differential positioning
|
|
Also known as Relative Positioning.
Precise measurement of the relative positions of two receivers tracking
the same GPS signals. Maybe considered synonymous with DGPS, or
the term may be reserved for the more precise carrier phase-based
baseline determination technique associated with GPS Surveying.
6 |
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digitise
|
|
A means of converting or encoding
map data that are represented in analog form into digital information
of x and y coordinates.1
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dilution of
precision (DOP)
|
|
An indicator of satellite geometry
for a unique constellation of satellites used to determine a position.
Positions tagged with a higher DOP value generally constitute poorer
measurement results than those tagged with lower DOP. There are
a variety of DOP indicators, such as GDOP (Geometric DOP), PDOP
(Position DOP), HDOP (Horizontal DOP), VDOP (Vertical DOP), etc.
6 |
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dithering
|
|
The introduction of digital noise
into the system. "Clock dithering" is the process by which
the U.S. Department of Defense (DoD) degrades the accuracy of the
Standard Positioning Service (i.e. absolute positioning of a C/A-Code
capable receiver). "Clock dithering" is the additional
satellite clock "bias" induced by the DoD's "Selective
Availability" policy that cannot be corrected for by the broadcast
Navigation Message clock correction parameters. 6 |
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doppler-aiding
|
|
A signal processing strategy that
uses a measured Doppler Shift to help the receiver smoothly track
the GPS signal. This allows for more precise velocity and position
determination, especially when the receiver is moving at high speed
and/or in an erratic fashion. 6 |
| |
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doppler shift
|
|
The apparent change in the frequency of
a signal caused by the relative motion of the transmitter and
receiver. 6
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double-difference
|
|
A data processing procedure by which the
pseudo-range or carrier phase measurements made simultaneously
by two GPS receivers are combined so that, for any measurement
epoch, the observations from one receiver to two satellites are
subtracted from each other (in a so-called "between-satellite
single-difference") to remove that receiver's clock error
(or bias). (Similarly for the other receiver's observations to
the same two satellites.) Then the two single-differences are
subtracted so as to eliminate the satellite clock errors as well
as to reduce significantly the effect of unmodelled atmospheric
biases and orbit errors. (The order may be reversed, i.e., take
"between-receiver single-differences" to each satellite
in turn, and then difference between the single-differences.)
The resulting set of Double-Differenced observables (for all independent
combinations of two-satellite-two-receiver combinations) can be
processed to solve for the baseline (linking the two receivers)
components and, in the case of ambiguous carrier phase measurements,
the integer ambiguity parameters. All high precision positioning
techniques use some form of Double-Difference processing: pseudo-range,
unambiguous carrier phase within a "bias-fixed" solution
(i.e., after the double-differenced ambiguity values have been
estimated and applied to the original carrier measurements), or
ambiguous carrier phase data within a "bias-free" solution.
6
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double precision
|
|
Refers to a level of coordinate
accuracy based on the possible number of significant digits that
can be stored for each coordinate. Whereas single precision coverages
can store up to 7 significant digits for each coordinate and therefore
retain a precision of +/- 5 meters in an extent of 1,000,000 meters,
double precision coverages can store up to 15 significant digits
per coordinate, and therefore retain the accuracy of much less
than 1 meter at a global extent.1
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dual-frequency
|
|
Refers to the instrumentation
that can make measurements on both L-Band frequencies, or to the
measurements themselves (e.g., L1
and L2
pseudo-range or carrier phase measurements). Dual-frequency measurements
are useful for high precision (pseudo-range-based) navigation because
the Ionospheric Delay bias can be determined, and the data corrected
for it. In the case of Double-Differenced carrier phase, dual-frequency
observations can account for the residual ionospheric bias (for
case of long baselines), or aid Ambiguity Resolution for "rapid
static" or "kinematic" baseline determination. All
"top-of-the-line" GPS receivers are of the dual-frequency
variety, and are comparatively expensive because of the special
signal processing techniques that must be implemented to make measurements
on the L2 carrier under the policy of Anti-Spoofing. 6 |
| |
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dynamic
positioning
|
|
See 'kinematic positioning'
|
|
e
|
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eastings
|
|
The x-coordinates in a plane
coordinate system.1
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| |
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ephemeris
|
|
The file of values from which
a satellite's position and velocity (the so-called "satellite
state vector") at any instant in time can be obtained. The
"Broadcast Ephemeris (or Ephemerides)" for a satellite
are the predictions of the current satellite position and velocity
determined by the Master Control Station, uploaded by the Control
Segment to the GPS satellites, and transmitted to the user receiver
in the Data Message. "Precise Ephemeris (or Ephemerides)"
are post-processed values derived by, for example, the International
GPS Service (IGS), and available to users post-mission via the Internet.
6 |
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ephemeris errors
|
|
Errors (or "biases")
which are present in the (Broadcast or Precise) Ephemeris data.
Broadcast Ephemeris errors are typically at the few metre level,
while Precise Ephemeris errors are at the decimetre-level. Ephemeris
errors are largely mitigated by differential correction (in DGPS
Positioning) or in double-differenced observables (formed from carrier
phase measurements) when the receivers are not up to a few tens
of kilometres apart. In very high precision applications and/or
where the baseline lengths are hundreds or thousands of kilometres,
residual Ephemeris Errors may limit the accuracy of the baseline
solution. 6 |
| |
|
|
|
estimated time of arrival (ETA)
|
|
The time of day of your arrival
at your destination. Typically used for navigation applications.
6 |
| |
|
|
|
estimated time enroute
(ETE)
|
|
The time left to your destination at your present speed. Typically
used for navigation applications. 6
|
|
|
|
|
|
f
|
|
|
|
face left
|
|
Face left refers to the position
of a theodolote when the vertical circle is situated to the left
hand side of the observer's face. |
| |
|
|
|
face right
|
|
Face right refers to the position of a theodolote when the vertical
circle is situated to the right hand side of the observer's face.
|
| |
|
|
|
Federal Radionavigation
Plan (FRP)
|
|
Congressionally mandated, joint
US Department of Defense (DOD) and US Department of Transportation
(DoT) effort to reduce the proliferation and overlap of federally
funded radionavigation systems. The FRP is designed to delineate
policies and plans for US government-provided radionavigation services.
Produced annually. 6 |
| |
|
|
|
fix
|
|
A single position with latitude,
longitude (or grid position), altitude (or height), time, and date.
6 |
|
g
|
|
|
|
GCP
|
|
ground control point
|
|
|
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|
|
geocode
|
|
A location in geographic space
converted into computer readable form. This usually means making
a digital record of the point's coordinates. |
| |
|
|
|
geocoding
|
|
The activity of defining the position
of geographical objects relative to a standard reference grid.
2 The conversion of analog maps
into computer readable form. The two usual methods of geocoding
are scanning and digitizing.
|
| |
|
|
|
geodetic survey
|
|
Global surveys for the establishment
of control networks (comprised of Reference or Control Points),
which are the basis for accurate land mapping. Maybe carried out
using either terrestrial or satellite positioning (e.g. GPS) techniques.
The outcome is a network of benchmarks which are a physical realisation
of the Geodetic Datum or Reference System. 6 |
| |
|
|
|
geodetical
surveying
|
|
The determination of the position
of points on the earth’s surface accounting for its curvature,
rotation and gravitational field. 2
|
| |
|
|
|
geographical data
|
|
Data that record the location and
a value characterizing the phenomenon.2
|
| |
|
|
|
geographic information
system
|
|
An organized collection of computer
hardware, software, geographic data and personnel designed to
efficiently capture, store, update, manipulate, analyse, and display
forms of geographically referenced information.1
A computer-based system that is capable of collecting, managing
and analysing geospatial data. This capability includes storing
and utilising maps, displaying the results of data queries and
conducting spatial analysis. 6
|
| |
|
|
|
geoid
|
|
The fundamental surface in Geodesy.
It is defined as the equipotential surface of the gravity field
that most closely approximates the Mean Sea Level. (The MSL deviates
from the Geoid surface by 1-2 metres due to the Sea Surface Topography
caused by wind-driven or geostrophic currents.) The Geoid is the
Vertical Datum surface both from a mathematical viewpoint (i.e.,
the sum of the Orthometric Height and the Geoid Height equals the
Ellipsoidal Height of a point), as well as in practice by making
the land height system synonymous with "height above MSL".
Models of the Geoid Height have been determined from the combined
processing of satellite-derived potential models, surface gravity
observations and the ocean gravity anomalies derived from Satellite
Altimetry. Their accuracy may range from a few metres in the open
ocean areas, down to the few decimetre level in land areas where
there is a good coverage of surface gravity. 6 |
| |
|
|
|
geometric
dilution of
precision (GDOP)
|
|
See Dilution of Precision. An
indicator of the geometrical strength of a GPS constellation used
for a position/time solution. 6 |
| |
|
|
|
global navigation satellite
system (GNSS)
|
|
This is an umbrella term used
to describe a generic satellite-based navigation/positioning system.
It was coined by international agencies such as the International
Civil Aviation Organisation (ICAO) to refer to both GPS and GLONASS,
as well as any augmentations to these systems, and to any future
civilian developed satellite system. For example, the Europeans
refer to GNSS-1 as being the combination of GPS and GLONASS, but
GNSS-2 is the blueprint for an entirely new system. 6 |
| |
|
|
|
global orbiting navigation
satellite system (GLONASS)
|
|
This is the Russian counterpart
to GPS. It consists of a constellation of 24 satellites (though
the number may vary due to difficulties in funding for the system)
transmitting on a variety of frequencies in the ranges from 1597-1617MHz
and 1240-1260MHz (each satellite transmits on two different L1
and L2
frequencies). GLONASS provides worldwide coverage, however, its
accuracy performance is optimised for northern latitudes, where
it is better than GPS's SPS (there being no "Selective Availability"
on GLONASS satellites). GLONASS positions are referred to a different
Datum to those of GPS, i.e. PZ90 rather than WGS84. 6 |
| |
|
|
|
global positioning system
(GPS)
|
|
A system for providing precise
location which is based on data transmitted from a constellation
of 24 satellites. It comprises three segments: (a) the Control Segment,
(b) the Space Segment, and (c) the User Segment. 6
global positioning system,
a set of satellites in geostationary earth orbits used to help determine
geographic location anywhere on earth by means of portable electronic
receivers.
2
|
| |
|
|
|
GPS surveying
|
|
Conventional static GPS surveying has the following characteristics:
(1) The points being coordinated are not moving, i.e. they are
"static".
(2) GPS data are collected over some "observation session",
typically ranging in length from an hour to several hours (or
perhaps days for very precise GPS Geodesy applications).
(3) The results are not required immediately, for in-the-field
use.
(4) The relative positioning mode of operation is the only mode
employed, requiring the use of a minimum of two GPS receivers
for all survey work.
(5) The measurements used for data reduction are those made on
the transmitted L-Band carrier wave, requiring specialised hardware
and software.
(6) A variety of processing algorithms can be employed, including
"bias-free" and "bias-fixed" solutions.
(7) Mostly associated with the traditional surveying and mapping
functions.
Since the late 1980's considerable attention has been paid to
the first three points, as they were considered to be unnecessarily
restrictive for typical GPS surveying applications. As a result
of vigorous R&D, new GPS surveying methodologies have been
developed, which complement the "conventional static"
technique. These modern GPS Surveying techniques are given a variety
of names but the following are considered generic: (a) rapid static
positioning techniques, (b) "stop & go" techniques,
and (c) "on-the-fly" positioning techniques.
Each of the techniques represents a technological solution to
the problem of obtaining high productivity (measure as many baselines
in as short a period of time as possible) and/or versatility (for
example, the ability to obtain results even while the receiver
is in motion) without sacrificing very much in terms of accuracy
and reliability. None of these techniques is as accurate or reliable
as conventional static GPS surveying, and each of these techniques
has its special strengths and weaknesses. They represent the state-of-the-art
in precision carrier phase-based GPS positioning, and are a direct
outcome of considerable innovation by instrument manufacturers
seeking to address surveying and non-surveying applications. 6
|
| |
|
|
|
GPS time (GPST)
|
|
GPST is a form of Atomic Time,
as is, for example, Coordinated Universal Time (UTC). GPST is "steered"
over the long run to keep within one microsecond of UTC. The major
difference is that while "leap seconds" are inserted into
the UTC time scale every 18 months or so to keep UTC approximately
synchronised with the earth's rotational period (with respect to
the sun), GPST has no leap seconds. At the integer second level,
GPST matched UTC in 1980, but because of the leap seconds inserted
since then, GPST is now (end 1998) ahead of UTC by 12 seconds (plus
a fraction of a microsecond that varies from day to day). The relationship
between GPST and UTC is transmitted within the Navigation Message.
6 |
| |
|
|
|
graticule
|
|
A
grid of parallels and meridians on a map.1 |
| |
|
|
|
grid
|
|
(1)
a set of regularly spaced sample points; (2) in cartography, an
exact set of reference lines over the earths surface.
2
A map coordinate system that projects the surface of the earth onto
a flat surface such as a "map", using square zones for
position measurements. Common map grids include that defined by
the UTM (Universal Transverse Mercator) projection. 6 |
|
h
|
|
|
|
height
(ellipsoidal)
|
|
The
height coordinate determined from GPS observations is related to
the surface of a reference ellipsoid. The coordinates are derived
initially in the 3-D Cartesian system (as XYZ values), and then
for display/output purposes they are transformed to latitude, longitude
and (ellipsoidal) height using well known formulae to an ellipsoid
such as that associated with the WGS84 Datum (semi-major axis: 6378137m;
inverse flattening: 298.257223563). The surface of the ellipsoid
is the zero ellipsoidal height datum. In relative positioning, the
height component of the receiver whose coordinates are being determined
relative to the base station can also be related to an ellipsoid
by transforming the baseline vector from the 3-D form (DXDYDZ) to
a change in latitude, change in longitude, and change in ellipsoidal
height. 6 |
| |
|
|
|
height
(orthometric)
|
|
The orthometric height is the height
of a station on the earth's surface, measured along the local
plumbline direction through that station, above the geoid surface.
It is approximated by the "Height Above Mean Sea Level",
where the MSL Datum is assumed to be defined by the mean tide
gauge observations over several years. The relationship between
orthometric height (H) and ellipsoidal height (h) is : h = H +
N, where N is the geoid height or geoid undulation with respect
to the reference ellipsoid. Orthometric height is traditionally
derived from geodetic levelling (using such techniques as optical
levelling, trigonometrical levelling, barometric levelling).
6
|
|
i
|
|
|
|
interpolation
|
|
The estimation of values of
an attribute at unsampled points from measurements made at surrounding
sites.
2
|
| |
|
|
|
ionosphere,
ionospheric delay
|
|
The Ionosphere is that band of
atmosphere extending from about 50 to 1000 kilometres above the
earth's surface in which the sun's ultraviolet radiation ionises
gas molecules which then lose an electron. These free electrons
influence the propagation of microwave signals (speed, direction
and polarisation) as they pass through the layer. The Ionospheric
Delay on GPS signals is frequency-dependent and hence impacts on
the L1
and L2
signals by a different amount (unlike that within the Troposphere).
A linear combination of pseudo-range or carrier phase observations
on the L1 and L2 carrier waves can be created to almost entirely
eliminate the Ionospheric Delay. The resulting observable is known
as the Ionosphere-Free carrier phase (or pseudo-range). For single-frequency
receivers it is not possible to account for this signal bias in
this way. A broadcast model is contained within the transmitted
Navigation Message, however, it is a relatively poor model (unlikely
to account for more than 50% of the effect) as the Delay is very
difficult to predict. The magnitude of the Ionospheric Delay is
a function of the latitude of the receiver, the season, the time
of day, and the level of solar activity. The Delay in the Zenith
direction can be several tens of metres, increasing as the elevation
angle of the satellite signal reduces (being 3-5 times greater than
in the Zenith direction). The Delay is largely eliminated in Relative
or Differential Positioning, however, the residual Ionospheric Delay
increases as the baseline length increases and may be a significant
source of error (especially in the height component) for very high
precision GPS Geodesy. Even when using dual-frequency instrumentation,
the Ionospheric Delay can still cause problems during the process
of rapid Ambiguity Resolution when phase and range combinations
other than the Ionosphere-Free one are used. 6 |
| |
|
|
|
ionosphere-free
combination
|
|
This is a particular linear combination
of the observations made on the L1
and L2
carrier waves that eliminates (to the first order) the ionospheric
delay on the GPS observables. The ionosphere-free L1 carrier phase
combination (in units of L1 wavelengths) is:
f(L1)ion-free = a1.f(L1) + a2.f(L2)
with a1 = f12f12 - f22 and a2 = - f1f2f12 - f22 , f1 and f2 are
the frequencies of the L1 and L2 carrier waves respectively. (A
similar expression can be developed for the ionosphere-free L2
carrier phase.) The ionosphere-free pseudo-range combination (in
metric units) is:
Pion-free = b1.P(L1) + b2.P(L2)
with b1 = f12f12 - f22 and b2 = - f22f12 - f22
6
|
| |
|
|
|
independent
baseline
|
|
These are baselines observed using
GPS Relative Positioning techniques which are the minimum necessary
to transfer the Datum from one Base Station to all other stations
within a ground network. For example, if there are M stations, there
will be M-1 independent baselines linking all the stations. Any
extra baselines that are measured are "redundant" baselines
which may improve the quality and reliability of the station coordinates
after Network Adjustment. 6 |
| |
|
|
|
integrity
|
|
A quality measure of GPS performance
for critical applications such as civilian aviation. A high level
of integrity is sought for such applications. 6 |
| |
|
|
|
international GPS service
(IGS)
|
|
An initiative of the International Association
of Geodesy, as well as several other scientific organisations,
that was established as a service at the beginning of 1994. The
IGS comprises of many component civilian agencies working cooperatively
to operate a permanent global GPS tracking network, to analyse
the recorded data and to disseminate the results to users via
the Internet. The range of "products" of the IGS include
precise post-mission GPS satellite ephemerides, tracking station
coordinates, earth orientation parameters, satellite clock corrections,
tropospheric and ionospheric models. Although these were originally
intended for the geodetic community as an aid to carrying out
precise surveys for monitoring crustal motion, the range of users
has since expanded dramatically, and the utility of the IGS is
such that it is vital to the definition and maintenance of the
International Terrestrial Reference System (and its various "frame
realisations" ITRF92, ITRF94, ITRF96, etc.). 6
|
| |
|
|
|
international
terrestrial
reference
system (ITRS)
|
|
The most precise,
geocentric, globally-defined coordinate system or datum on the
earth's surface. It is a more accurate and more convenient a Satellite-Based
Datum than the WGS84 Datum. The various "frames" (such
as ITRF96, etc.) are realisations of the ITRS for a particular
epoch in time, consisting of a set of 3-D coordinates and velocities
for hundreds of geodetic stations around the world (all coordinates
of fixed stations on the earth change with time due to "continental
drift"). Although some of the stations are Satellite Laser
Ranging (SLR) stations, or Very Long Baseline Interferometry (VLBI)
stations, the vast majority are GPS tracking stations of the IGS
network. 6
|
|
j
|
|
|
|
|
|
|
|
k
|
|
|
|
kinematic
positioning
|
|
Kinematic Positioning refers
to applications in which the position of a non-stationary object
(vehicle, ship, aircraft) is determined. 6 |
| |
|
|
|
l
|
|
|
|
|
|
1575.42MHz GPS carrier frequency
which contains the C/A-Code,
the encrypted P-Code
(or Y-Code) and the Navigation Message. Commercial GPS navigation
receivers can track only the L1 carrier to make pseudo-range (and
sometime carrier phase and Doppler frequency) measurements. 6
|
| |
|
|
|
|
|
1227.60MHz GPS carrier frequency
which contains only the encrypted P-Code
(or Y-Code) and the Navigation Message. Military Y-Code capable
receivers can, in addition to making L1 measurements, make pseudo-range
measurements on the L2 carrier. The combination of the two measurements
(on L1 and L2) permits the Ionospheric Delay to be corrected for.
Dual-frequency GPS receivers intended for Surveying applications
can make L2 measurements using proprietary signal processing techniques.
Such measurements are essential if the Ionospheric Delay on carrier
phase is to be corrected for (especially on baselines of length
greater than about 20-30km) and/or where fast Ambiguity Resolution
is needed. 6 |
| |
|
|
|
LANDSAT
|
|
Land resource assessment satellite
system, a series of earth resource scanning satellites launched
by the USA.
2
|
| |
|
|
|
latitude
|
|
A method of measuring the earth representing
angles of a line extending from the center of the earth to the
earth’s surface. Lines of latitude run from east to west and measure
the number of degrees north or south of the Equator (which represents
0 degrees). Values range from the North Pole, at positive 90 degrees,
to the South Pole which is located at negative 90 degrees. Lines
of latitude are often called ‘parallels’.1
Each degree can be further subdivided into 60 minutes, each composed
of 60 seconds.
A north/south angular measurement of position relative to the
equator, in the meridian plane which contains the earth's rotation
axis. 6
|
| |
|
|
|
local area
augmentation
system (LAAS)
|
|
Plan by which Local Area Differential
GPS (LADGPS), which generates and transmits differential corrections
to appropriately equipped aircraft users, is augmented with integrity
messages transmitted from the ground and additional ranging signals.
LAAS is set up near a major airport, and consists of the DGPS reference
station, the integrity monitoring receiver and a pseudolite which
transmits "satellite-like" PRN-coded signals to incoming
aircraft. 6
|
| |
|
|
|
L-Band
|
|
The group of radio frequencies
extending from 390MHz to 1550MHz. The GPS carrier frequencies L1
and L2
are in the L-Band. 6 |
| |
|
|
|
longitude
|
|
A method of measuring the earth representing
angles of a line extending from the center of the earth to the
earth’s surface. A line extending from the north to the south
pole through the Greenwich, England, represents 0 degrees. Each
line of longitude runs north and south and measures the number
of degrees east or west of the Prime Meridian. Values range from
positive 180 to negative 180 degrees. Lines of longitude are often
called ‘meridians’. 1
An east/west angular measurement
of position in relation to the Prime Meridian. The angle between
the two great circles, one being the Prime (or Greenwich) Meridian
and the other a meridian passing through the point of interest.
(A great circle that passes through the north and south poles,
and hence contains the earth's rotation axis.)
6
|
|
m
|
|
|
|
map projection
|
|
A mathematical
model for converting locations on the earth’s surface from spherical
to planar coordinates, allowing flat maps to depict three-dimensional
features. Some map projections preserve the integrity of shape,
others preserve accuracy of area, distance or direction.1
All
map projections distort shape, area, distance or direction to
some extent.
|
| |
|
|
|
map units
|
|
The coordinate units in which the
geographical data are stored, such as meters, or degrees, minutes
and seconds.1
|
| |
|
|
|
mask angle
|
|
see cutoff angle |
| |
|
|
|
meridian
|
|
A line running vertically from the
north pole to the south pole along which all locations have the
same longitude. The prime meridian (0 degrees) runs through Greenwich,
England. Moving left or right of the prime meridian, measures
of longitude are negative to the west and positive to the east,
up to 180 degreees (half-way around the globe).1
|
| |
|
|
|
minimally
constrained
|
|
A form of least squares solution
in which the observed baseline vectors are treated as "observations"
in a secondary network adjustment (see Network Adjustment), and
only one coordinate must be held fixed to its known value while
all others are allowed to adjust. Typically GPS surveys measure
more baselines than the minimum needed to coordinate all the points
in the network. These extra "observations" are redundant
information that a minimally constrained network adjustment uses
to derive optimum estimates of the coordinate parameters, as well
as valuable quality information in the form of parameter standard
deviations and error ellipses (or ellipsoids). 6 |
| |
|
|
|
multi-channel
receiver
|
|
A GPS receiver that can simultaneously track
more than one satellite signal using a dedicated signal electronics
channel for each satellite. High quality receivers may have 12
channels for L1,
and another 12 channels for L2
signals. Lower quality GPS navigation receivers may have only
6 or 8 channels. In contrast to a Multiplexing Channel Receiver.
6
|
| |
|
|
|
multipath
|
|
Interference caused by reflected
GPS signals arriving at the receiver, typically as a result of nearby
structures or other reflective surfaces. May be mitigated to some
extent through appropriate antenna design, antenna placement and
special filtering algorithms within GPS receivers. 6 |
| |
|
|
|
multipath error
|
|
Errors caused by the interference
of a signal that has reached the receiver antenna by two or more
different paths. This is usually caused by one path being bounced
or reflected. The impact on a pseudo-range measurement may be up
to a few metres. In the case of carrier phase, this is of the order
of a few centimetres. 6 |
| |
|
|
|
multiplexing
channel
|
|
A channel of a GPS receiver that can
be sequenced through a number of satellite signals. In contrast
to a Multi-Channel Receiver in which one channel is dedicated
to each satellite signal. 6
|
|
n
|
|
|
|
navigation message
|
|
Also known as the Data Message, containing
the satellite's broadcast ephemeris, satellite clock (bias) correction
parameters, constellation almanac information and satellite health.
6
|
| |
|
|
|
NAVSTAR
|
|
The name sometimes given to the
GPS satellite system. NAVSTAR is an acronym for NAVigation Satellite
Timing and Ranging. 6 |
| |
|
|
|
network
adjustment
|
|
A form of least squares solution
in which the observed baseline vectors are treated as "observations"
in a secondary adjustment (see Minimally Constrained). It may be
a minimally constrained network adjustment with only one station
coordinate held fixed, or it may be constrained by more than one
fixed (known) coordinates. The latter is typical of a GPS survey
carried out to densify or connect some newly coordinated points
to a previously established control or geodetic framework (see Datum).
6 |
| |
|
|
|
NMEA
|
|
National Marine Electronics Association,
a U.S. standards body that defines message structure, content
and protocols to allow electronic equipment installed within ships
and boats to communicate with each other. GPS receivers can be
configured to output various types of messages in the "NMEA
format". 6
|
| |
|
|
|
northings
|
|
The y-coordinates
in a plane-coordinate system.1
|
|
o
|
|
|
|
OEM
|
|
Original Equipment
Manufacturer. Typically GPS receiver "boardsets" or "engines"
that a product developer can embed within some application or hardware
package. 6 |
| |
|
|
|
on-the-fly (OTF)
|
|
This is a form of Ambiguity Resolution (AR)
which does not require that the receivers remain stationary for
any length of time. Hence this AR technique is suitable for initialising
carrier phase-based Kinematic Positioning. For many applications
this introduces considerable flexibility. For example, aircraft
do not have to be parked on the ground in order to resolve the
carrier cycle ambiguities, and then require that signal lock-on
be maintained throughout the kinematic survey. However, dual-frequency
instrumentation capable of making both carrier phase and precise
(P-Code
level) pseudo-range measurements is required. 6
|
| |
|
|
|
order of survey
|
|
In an analogous manner to "Class
of Survey", Order of Survey is a means of categorising the
quality, or precision, of a static survey. However, it relates to
the external quality, and is influenced by the quality of the "external"
network information. The number of categories, the notation applied,
and the accuracy tolerances defining the transition from one order
to another are defined by individual nations. Typically they mirror
the categories of Class of Survey, hence an A Class survey may correspond
to a 1st Order survey. The labeling of a particular Order (e.g.
1st, 2nd, etc.) to a survey points within a "network"
(whether it is carried out using GPS or any other technique) is
performed as part of the process of Network Adjustment in which
the relative error ellipses (in the horizontal case) between coordinated
stations are computed and compared with the accuracy standards that
must be met for various categories of Order. However, unlike the
Minimally Constrained Network Adjustment that is a prerequisite
to establishing the Class of Survey, the Network Adjustment must
be constrained to the surrounding geodetic control. Hence a very
high quality GPS network (therefore a high Class survey) may be
distorted to "fit" the existing control which may have
been determined using a lower Class survey. The resulting Order
of the Survey would have to match the lower of either the Class
of the GPS survey or the Class of the existing geodetic control.
If the existing geodetic control is of a lower quality to what can
be achieved using modern GPS Surveying techniques, then the geodetic
control network must be upgraded or "renovated" using
more precise GPS Geodesy techniques. 6 |
| |
|
|
|
outage
|
|
Defined as a loss of Availability,
due to either there not being enough satellites visible to calculate
a position, or the value of the DOP indicator is greater than
some specified value (implying that the accuracy of the position
is unreliable). 6
|
|
|
|
|
|
p
|
|
|
| |
|
|
|
|
|
The Precise or Protected
code. A very long sequence of PRN binary biphase modulations on
the GPS L1 and L2
carrier at a chip rate of 10.23MHz, which repeats about every 267
days. Each one week segment of this code is unique to a GPS satellite
and is reset each week. Under the policy of "Anti-Spoofing"
the US Dept. of Defense has encrypted the P-Code (replacing it with
a so-called Y-Code). Only US military and other authorised users
are able to overcome AS using special receivers. 6
|
| |
|
|
|
phase-smoothed pseudo-range
|
|
The pseudo-range measurement which
has had its "noise" level (random errors) reduced by being
combined with the high precision carrier phase. It is still an unambiguous
"range" measurement which can be processed using the standard
algorithms of Point Positioning or Relative Positioning. 6 |
| |
|
|
|
pixel
|
|
One
picture element of a uniform raster or grid line. Often used synonymously
with cell.
1 |
| |
|
|
|
point
|
|
A
single x, y coordinate that represents a geographical feature too
small to be displayed as a line or area, e.g. a mountain peak.1 |
| |
|
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point positioning
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see Absolute Positioning |
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position
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The 3-D coordinates of a
point, usually given in the form of Latitude, Longitude, and Altitude
(or Ellipsoidal Height), though it may be provided in the 3-D Cartesian
form, or any other transformed map or geodetic reference system.
An estimate of error is often associated with a position.
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Position Dilution of
Precision (PDOP)
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See Dilution of Precision.
Measure of the geometrical strength of the GPS satellite configuration
for 3-D positioning. 6 |
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post-processed
GPS
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In post-processed (Differential
or Relative ) GPS the base and user (or roving or mobile) receivers
have no data communication link between them. Instead, each receiver
records the satellite observations that will allow differential
correction (in the case of pseudo-range-based positioning), or the
processing of double-differenced observables (in the case of carrier
phase-based positioning) at a later time. Data processing software
is used to combine and process the data collected from these receivers.
6 |
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Precise Positioning
Service (PPS)
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The most accurate Absolute Positioning
possible with GPS navigation receivers, based on the dual-frequency
encrypted P-Code.
Available to the military users of GPS. Typical accuracy is of the
order of 10-20m. 6 |
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precision
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If
applied to paper maps or map databases, it means the accuracy of
definition; (2) if applied to data collection devices such as digitisers,
it is the exactness of the determined value; (3) the number of significant
digits used to store numbers.1
Note:
precision is not the same as accuracy - a large number of significant
digits doesn't necessarily indicate that the measurement is accurate. |
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pseudolite
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A ground-based differential GPS
receiver which transmits a signal like that of an actual GPS satellite,
and can be used for ranging. Originally intended as an augmentation
for Local Area Augmentation Systems to aid aircraft landings. However,
pseudolites may also be used where signal obstructions are such
that insufficient GPS satellites can be tracked. In fact, pseudolites
are feasible in circumstances where no satellite signals are observable,
e.g. for indoor applications. 6 |
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Pseudo-Random
Noise (PRN)
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A binary signal with random noise-like
properties. It is generated by mathematical algorithm or "code",
and consists of repeated pattern of 1's and 0's. This binary code
can be modulated on the GPS carrier waves using Binary Shift-Key
(BSK) modulation. The C/A-Code and the P-Code
are examples of PRN codes. Each satellite transmits a unique C/A-Code
and P-Code
sequence (on the same L1
and L2
frequencies), and hence a satellite may be identified according
to its "PRN number", e.g. PRN2 or PRN14 are particular
GPS satellites. 6 |
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pseudo-range
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A distance measurement
based on the correlation of a satellite's transmitted code (may
be the C/A-Code or the encrypted P-Code)
and the local receiver's reference code (for that PRN satellite
number), that has not been corrected for errors in synchronisation
between the transmitter's clock and the receiver's clock. Hence
a pseudo-range measurement is a time-error biased distance measurement.
The precision of the measurement is a function of the resolution
of the code, hence C/A-Code pseudo-range measurements may have
a "noise" at the few metre level for standard GPS receivers
(and at the sub-metre precision level in the case of so-called
"narrow correlator" GPS receivers). 6
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q
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r
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range
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A fixed distance between
two points, such as between a starting and an ending waypoint, or
a satellite and a GPS receiver. May also be referred to as Geometric
Range. 6 |
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Real Time
Kinematic (RTK)
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The Relative Positioning procedure
whereby carrier phase measurements (or corrections) are transmitted
in real-time from a Reference or Base Station to the user's roving
receiver. Centimetre accuracy is achieved without the need to record
and post-process double-differenced carrier phase observables. 6 |
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Real-Time DGPS
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A Base Station computes,
formats, and transmits pseudo-range corrections via some sort of
data communication link (e.g., VHF or UHF radio, cellular telephone,
FM radio sub-carrier or satellite com link). The roving receiver
requires some sort of data link receiving equipment to receive the
transmitted DGPS corrections so that they can be applied to its
current observations. Most GPS receivers are so-called "RTCM-capable",
which means that they can accept industry standard DGPS correction
messages if the real-time data link is provided. 6 |
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rectify
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The process by which
and image or grid is converted form image coordinated to real-world
coordinates. Rectification typically involves rotation and scaling
of grid cells and thus requires resampling of values.
1 |
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Receiver Autonomous
Integrity Monitoring (RAIM)
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A form of receiver self-checking
in which redundant pseudo-range observations are used to detect
if there is a problem or "failure" with any of the measurements
-- only four measurements are needed to derive 3-D coordinates and
the receiver clock error, hence any extra measurements can be used
for checking. Once the failed measurements have been identified
they may be eliminated from the navigation fix. RAIM is a concept
that has been introduced by aviation users who are concerned that
GPS does not have the level of Integrity necessary for non-precision
airport approaches or GPS-aided landing. 6 |
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relative positioning
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The determination of relative positions
between two or more receivers which are simultaneously tracking
the same GPS signals. One receiver is generally referred to as
the Reference or Base Station, whose coordinates are known in
the satellite datum. The second receiver may be stationary or
moving. However its coordinates are determined relative to the
Base Station. In carrier phase-based positioning this results
from the determination of the baseline vector, which when added
to the Base Stations coordinates generates the User's coordinates.
In pseudo-range-based GPS positioning, the coordinates are derived
from the User receiver's observations after they have had the
differential corrections applied (either in the real-time or post-processed
mode). 6
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RINEX
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Receiver INdependent EXchange format.
A set of standard definitions and formats to promote the free
exchange of GPS data and facilities the use of data from any GPS
receiver with any post-processing software package. The format
includes definitions for three fundamental GPS observables: time,
phase, and range. 6
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root mean square
error (RMS)
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The Root Mean Square (RMS) error represents
the difference between original control points and new control
point locations calculated by the transformation process (e.g.
during digitising). The transformation scale indicates how much
the map being digitized will be scaled to match the real-world
coordinates.
Where:
x is the error in one dimension of a point
n is the number of points in the sample
The statistic is calculated for each
dimension (Eastings and Northings).
The vector error is computed by combining these results:
Where:
E is the error in Eastings of a point
N is the error in Northings of a point
n is the number of points in the sample 5
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rover
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Any mobile GPS receiver
collecting data during a field session. The receiver's position
may be computed relative to another, stationary GPS receiver at
a Base Station. May also be referred to as the Mobile Receiver.
6 |
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Radio Technical Committee
for Maritime Applications (RTCM)
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RTCM Special Committee 104 has
developed standard message types for use by differential GPS transmitting
stations. The message content has been defined and hence when the
RTCM-104 standard (version 2.2 is the latest) is implemented within
a user receiver, it is able to decode and apply the DGPS corrections
to its raw data in order to generate a DGPS-corrected coordinate.
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R95
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A position
accuracy measure. The R95 value is defined as a circle's radius,
when centred at the true position, encloses 95% of the data points
in a horizontal scatter plot. 6 |
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s
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scale
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The relationship existence between
distance on a map and the corresponding distance on the earth.
It is usually expressed in the following form 1:10,000, meaning
that 1 unit of measurement on the map represents 10,000 of the
same units on the earth’s surface.1
A ‘ large’ scale map is one in which a given part of the Earth
is represented by a large area on the map. Large scale maps generally
show more detail than small scale maps because at a large scale
there is more space on the map in which to show features. Large
scale maps are typically used to show site plans, local areas,
neighborhoods, towns etc. 1:2,500 is an example of a large scale.
A ‘small’ scale map is one in which a given part of the Earth
is represented by a small area on the map. Small scale maps generally
show less detail than large scale maps, but cover large parts
of the Earth. Maps with regional, national, and international
extents typically have small scales, such as 1:1,000,000. Large
scale maps typically show more detail than small scale maps, whereas
on smaller scale maps there is simply not enough room to show
all the available detail, so features such as streams and roads
often have to be represented as single lines, and area features
like cities, have to be shown as points. This is called generalization.
4
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selective
availability (SA)
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Intentional
degradation of the Absolute Positioning performance capabilities
of the NAVSTAR satellite system for civilian use (the Standard Positioning
Service) by the U.S. military, accomplished by artificially "dithering"
the clock error in the satellites. Has generally been mitigated
through the use of Relative Positioning techniques. SA was activated
on 25 March 1990, and was removed on the 1st May 2000 (midnight
Washington D.C. time). 6 |
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sexagesimal
system
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The sexagesimal system is one
form of units used to describe angular measurement. A circle is
divided into 360 degrees, a degree is divided into 60 minutes
and a minute is divided into 60 seconds.
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SINEX
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Solution Independent Exchange
format. A solution output format recently developed by geodesists
to permit the exchange of solution information between organisations,
from which the original normal equation systems for precise GPS
adjustments can be reconstructed. These reconstructed equation systems
can be combined with other normal equation systems to create new
GPS baseline solutions. 6 |
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single precision
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A lower level of coordinate
accuracy based on the possible number of significant digits which
can be stored for each coordinate. Single precision numbers can
store up to 7 significant digits for each coordinate and therefore
retain a precision of +/- 5 meters in an extent of 1,000,000 meters,
double precision coverages can store up to 15 significant digits
per coordinate (typically 13 to 14 significant digits) and therefore
retain the accuracy of much less than 1 meter at a global extent.1
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space segment
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The space-based component
of the GPS system (i.e., the orbiting satellites and their signals).
The satellites may be differentiated into various groups. e.g. the
Block II, Block IIA, Block IIR, and Block IIF satellites. 6 |
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Spherical Error
Probable (SEP)
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A statistical measure of
the 3-D positioning precision. The SEP value is defined as a sphere's
radius, when centred at the true position, encloses 50% of the data
points in a 3-D scatter plot. Thus, half the data points are within
a 3-D SEP sphere and half are outside the sphere. 6
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Standard
Positioning
Service (SPS)
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The civilian Absolute Positioning
accuracy obtained by using the pseudo-range data obtained with the
aid of a standard single-frequency C/A-Code GPS receiver. Under
"Selective Availability" the horizontal accuracy is stated
to be 100m 2drms (or 95% of the time). 6 |
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static positioning
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Location determination when
the receiver's antenna is presumed to be stationary on the earth.
In the case of pseudo-range-based techniques this allows the use
of various averaging techniques to improve the accuracy. Static
Positioning is usually associated with GPS Surveying techniques,
where the two GPS receivers are static for some observation period
which may range from minutes to hours (and even in the case of GPS
geodesy, several days). 6
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Stop-and-Go Positioning
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This is a GPS Surveying "high productivity"
technique which is used to determine centimetre accuracy baselines
to static points, using site observation times of the order of
1 minute. Only carrier phase that has been converted into unambiguous
"carrier pseudo-range" is used, necessitating that the
ambiguities be resolved BEFORE the survey starts (and again at
any time the satellite tracking is cut, e.g. due to signal obstructions).
It is known as the "stop & go" technique because
the coordinates of the receiver are only of interest when it is
stationary (the "stop" part), but the receiver continues
to function while it is being moved (the "go" part)
from one stationary setup to the next. As the receiver must track
the satellite signals at all times, hence the transport of the
receiver from one static point to another must be done carefully.
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t
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track (TRK)
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The direction of movement relative
to a ground position. Commonly associated with navigation applications.
6
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transformation
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The process of converting data from
one coordinate system to another through translation, projection,
rotation and scaling. 1,
2
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triple-difference
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A linear combination of Double-Difference
carrier phase observables by which the cycle ambiguity parameters
can be eliminated and which is less affected by unrepaired cycle
slips than Double-Differences. A Triple-Differenced observable is
created by differencing two consecutive Double-Differences (the
same pair of receivers and the same pair of satellites, but separated
in time). A useful observable for obtaining approximate baseline
solutions or for detecting cycle slips in the Double-Differenced
observables. 6 |
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trivial baseline
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Trivial baselines are those baselines formed
when more than two GPS receivers are used simultaneously in the
field to perform static GPS surveys. For example, when 3 receivers
at points A, B, C are deployed only 2 baselines are independent
(either A-B & A-C, AB & B-C, or AC & C-B), with the
other one being trivial. This trivial baseline may be processed,
but because the data used for this baseline has already been used
to process the independent baselines, the baseline results should
not be used for Network Adjustment or for quality control purposes
unless the statistics (and variance-covariance matrix) are appropriately
downweighted. 6
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troposphere,
tropospheric delay
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The troposphere is the neutral atmosphere
comprising the lower 8km of the atmosphere. The tropospheric delay
on GPS signals is of the non-dispersive variety because it is
not frequency-dependent and hence impacts on both the L1
and L2
signals by the same amount (unlike that within the Ionosphere).
The wet and dry components of the Troposphere cause the Delay
to the signals, with the wet component be responsible for approximately
10% of the total delay. Various Tropospheric Delay models have
been developed to estimate the Delay as a function of the satellite
elevation angle, receiver height, and meteorological parameters
such as temperature, pressure and humidity. The Delay in the Zenith
direction is approximately 2.5m, increasing as the elevation angle
of the satellite signal reduces. (This behaviour is described
by the so-called Mapping Function, so that the Delay near the
horizon is 3-5 times higher than in the Zenith direction.) The
Delay is largely eliminated in Relative or Differential Positioning,
however the residual Tropospheric Delay increases as the baseline
length increases and may be a significant source of error (especially
in the height component) for very high precision GPS Geodesy.
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u
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UTC (Coordinated
Universal Time)
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Formerly referred to as GMT or Greenwich
Mean Time. This is the basis of "civilian time". 6
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universal
transverse
mercator
(UTM)
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A widely used
planar coordinate system, extending from 84 north to 80 south
latitude and based on a specialised application of the Transverse
Mercator projection. The extent of the coordinate system is broken
into 60, 6 degrees (longitude) zones. Within each zone, coordinated
are usually expressed as meters north or south of the equator
and east from a reference axis. For locations in the Northern
Hemisphere, the origin is assigned a false easting of 500,000
and a false northing of 0. For locations in the Southern Hemisphere,
the origin is assigned a false easting of 500,000 and a false
northing of 10,000,000.1
A grid coordinate system that projects global sections onto a
flat surface to measure position in specific zones. These zones
are 6° wide and are stepped along the equator such that each
zone corresponds to a north-south strip of the earth. 6
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user segment
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That component of the GPS
system that includes the user equipment, applications and operational
procedures. 6 |
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v
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w
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waypoint
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A (usually two-dimensional) coordinate
that is input into a navigation device, such as a GPS receiver,
representing a position that a vessel, aircarft, vehicle or person
has to navigate to, with the aid of GPS (and/or any other position
fixing device). 6 |
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Wide Area Augmentation System (WAAS)
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WAAS is a US Federal Aviation
Authority (FAA) funded system of equipment and software that augments
GPS accuracy, availability and integrity. The WAAS provides a satellite
signal for WAAS users to support enroute and precision approach
aircraft navigation. Similar systems are under development in Europe
(where it is known as EGNOS -- European Geostationary Navigation
Overlay System), Japan (where it is known as MT-SAT), and Australia.
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World Geodetic System
1984 (WGS84)
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A global Geodetic Datum defined and maintained by the US Department
of Defense. As the Control Segment coordinates and the Broadcast
Ephemerides are expressed in this Datum, the GPS positioning results
are said to be in the WGS84 Datum. In the case of Point Positioning
this is largely true, although the level of accuracy achievable
under the policy of Selective Availability is so poor that the
link to the WGS84 Datum is very approximate. In the case of Relative
Positioning, the baseline vector may be determined to quite high
accuracy (at the sub-centimetre level using precise GPS Surveying
techniques), however the coordinate (and therefore the Datum)
of the unknown point is almost completely defined by the Datum
of the Base Station. This may not be coincident with the WGS84
Datum at better than a few tens of metres! If GPS Geodesy techniques
are used, with known station coordinates expressed in the ITRS
and precise ephemerides obtained from the IGS, it is more correct
to state that the subsequent set of coordinates are expressed
in one of the ITRS frames (e.g. ITRF92, ITRF94, etc.). The WGS84
and the ITRS are compatible at the one metre level. However, the
ITRS is a more precise realisation of an earth-fixed, earth-centred
terrestrial reference system. 6
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x
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y
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Y-Code
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The term used to refer to
the encrypted P-Code, generated
within the satellites and transmitted on both the L1
and L2 carrier signals under the
policy of "Anti-Spoofing". Civilian GPS receivers use
proprietary signal processing techniques to make measurements of
pseudo-range and carrier phase on both L-Band frequencies. 6 |
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z
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zero baseline
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A zero baseline test can be used
to study the precision of receiver measurements (and hence its correct
operation), as well as the data processing software. The experimental
setup, as the name implies, involves connecting two GPS receivers
to the same antenna. When two receivers share the same antenna,
biases such as those which are satellite (clock and ephemeris) and
atmospheric path (troposphere and ionosphere) dependent, as well
as errors such as multipath CANCEL during data processing. The quality
of the resulting "zero baseline" is therefore a function
of random observation error (or noise), and the propagation of any
receiver biases that do not cancel in double-differencing.
6
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z-value
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The elevation value of a
surface at a particular x, y location. Also known as the spot value
or spot elevation. 1 |
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1
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