GNSS Introduction and Principles of Operation PDF

Summary

This document provides an introduction to global navigation satellite systems (GNSS), covering the principles of operation and learning outcomes. The document explains the components, functions, and technologies associated with GNSS, including satellite positioning, signal transmission, and receiver operation. It's a useful resource for learning about this technology.

Full Transcript

Global Positioning Systems (GPS)
and
Global Navigation Satellite Systems (GNSS)
Introduction and Principles of Paul Hinds PhD,
Learning Outcomes
Introduction
GPS Overview
GPS Signal
How GPS positions are measured
Sources of Errors
How to improve GPS accuracy
Global Navigation Satellite System (GNSS)
Introduction
During the 1970’s global positioning systems (GPS) emerged out of the space
program and relied on signals transmitted from satellites.
First paid for and developed by the military.
The entire scope of satellite systems used in positioning is now referred to as
global navigation satellite systems (GNSS)
Provide precise timing and positioning information anywhere on the earth
surface.
Can operate day or night, rain or shine and do not require a clear line of sight
between surveying stations.
A departure from convention surveying procedures, which rely on observed
angles and distances to determine point positions.
Global Positioning Systems
(GPS) Overview
GPS is a satellite-based navigation system operated by the US government.
Consists of a network of a minimum of 24 satellites that orbit the earth.
The satellites emit signals (radio waves) that are picked-up on earth by GPS
receivers.
To determine its location on earth, the receiver requires signals from
a minimum of three different satellites but, best to use at least four.
Was originally intended for military applications but has been made available
for civilian use since the 1990s.
GPS is a type of Global Navigation Satellite System (GNSS).
GPS Satellite
GPS satellites are positioned
in precise, circular orbits
18,000 kilometers (11,000
miles) above the Earth. They
orbit once every 12 hours.
The precise travel time of the
signal from these satellites is
necessary to determine the
distance or range to the
satellite

GPS Constellation | Time and Navigation (si.edu)
Global Positioning Systems (GPS)
Overview
GPS consists of three segments: space,
control, and user
 The Space Segment: consists of a
minimum of 24 operational satellites in six
circular orbits 18,000 km (11,000 miles)
above the earth at an inclination angle of
55 degrees with an 11 hour 58 minute
period.
 Typically, the satellites are spaced in
primary orbital slots so that at any time a
minimum of 6 satellites will be in view to
users anywhere in the world.
 Global
Positioning
Systems (GPS)
Overview
The Control Segment: consists of a master
control station in Colorado Springs. Current
Operational Control Segment includes a master
control station, 11 command and control
antennas, and 16 monitoring sites
The monitor stations track the position all GPS
satellites in view and collect ranging
information from the satellite over time.
The monitor stations send the information they
collect from each of the satellites back to the
master control station, which computes
extremely precise satellite orbits and make
future predictions of the orbits.
The information is then formatted into updated
navigation messages for each satellite. The
information is then uploaded to the satellite to https://www.gps.gov/multimedia/images/GPS-
be used by receivers to predict satellite control-segment-map.pdf
positions.
Global Positioning Systems
(GPS) Overview
The User Segment: consists of the receivers, processors, and antennas that
allow land, sea, or airborne operators to receive the GPS satellite broadcasts
and compute their precise position, velocity and time.
Consist of two categories;
 The Standard Position Service (SPS) – use the L1 and L2 broadcast frequency
(1575.42 and 1227.60 MHz frequencies respectively). These are pseudo-
random codes for timing and contains a navigation message with ephemeris
data.
- Ephemeris data is used by GPS receivers to estimate location relative to the
satellites and as a result position on earth
 The Precise Position Service (PPS) – broadcast on both the L1 and L2 frequency
but only available to the military.
 GPS Signal
To independently determine ground position in real
time a system of accurate measurement of signal
travel time from satellite to receiver is necessary.
Carrier adjusted with pseudorandom noise (PRN)
codes consisting of unique sequences of binary
values (zeros and ones) generated according to a
special mathematical algorithm.
Satellites transmit two or more different PRN codes
L1 frequency is modulated with the precise code
(P-code) and also a coarse/acquisition code (C/A
code).
The P-code, however, is normally encrypted and is
available only to authorized users (Military use),
approximate 10 times more accurate than the C/A
code – makes correction to ionosphere refraction
which is the largest error source in positioning..
C/A code allows receivers to acquire satellite as well
as allowing receivers to determine their approximate
position.
 How GPS position is measured
Satellite send out a broadcast message
with precise time PRN code is broadcast
with a starting time indicating the front
edge of one chip.
Receiver simultaneously generates a
duplicate PRN code.
Matching the incoming satellite signal
with the identical receiver-generated
signal derives the time it takes for the
signal to travel from satellite to
receiver.
The signal delay is converted to travel
time and the known signal velocity, the
distance to the satellite can be
computed.
 How GPS
position is
measured
Knowing:
Satellite position and pseudo random
code information (ephemeris or
almanac data)
Speed of signal 300,000 km/s (speed
of light)
The position of the receiver can be
calculated using trilateration
A minimum of 4 line-of-sight satellites
are required.
Timing of the signals needs to be VERY
Distance between the receiver and the satellites = propagation time x radio
precise, so an atomic clock is used. wave speed - Search Images (bing.com)
Latitude and longitude can be
calculated quite precisely (under the
right conditions) but elevation will How does GPS work? (youtube.com)
always be the weak axis.
GPS Error Sources
 Instrument Errors
i. Clock biases: both receiver and satellite clocks are subject to errors. Can
be removed mathematically.
GPS position calculations, depend on measuring signal transmission time
from satellite to receiver; this, in turn, depends on knowing the time on
both ends. NAVSTAR (NAVigation Satellite Timing and Ranging) satellites use
atomic clocks. These errors are minimized by calculating clock corrections
(at monitoring stations) and transmitting the corrections along with the
GPS signal to appropriately GPS receivers.
ii. Receiver noise: The electronic of the receiver operate within a specific
tolerance. Small variation occur in the generation and processing of the
signals that can translate into errors in the pseudorange and carrier-phase
observation. Periodic calibration checks and test of receiver electronics
should be made
 GPS Error Sources
 Natural Errors
i. Refraction: due to the transit of signals
through the atmosphere signals from the
satellite are delayed.
Upper atmosphere (ionosphere): As GPS
signals pass through the upper atmosphere
(the ionosphere 50-1500km above the surface),
signals are delayed and deflected. By modeling
ionosphere characteristics, GPS monitoring
stations can calculate and transmit corrections
to the satellites, which in turn pass these
corrections along to receivers.
- Troposphere (lowest part of the atmosphere
– 10-12 km in altitude
- Stratosphere goes up to 50 km https://gisgeography.com/gps-accuracy-hdop-
pdop-gdop-multipath/
GPS Error Sources
 Natural Errors
ii. Multipath Effects: GPS signals travel from
satellites through the atmosphere directly to
GPS receivers. GPS receivers must discriminate
between signals received directly from satellites
and other signals reflected from surrounding
objects, such as buildings, trees, and even the
ground.
- Multipath errors are particularly common in
urban or woody environments, especially those
with large valleys or mountainous terrain.
Ghilani, 2022

https://gisgeography.com/gps-accuracy-hdop-pdop-
gdop-multipath/
Dilution of Precision
Accuracy of GPS positioning is affected by the arrangement of satellites in the
sky.
The ideal arrangement (of the minimum four satellites) is one satellite directly
overhead, three others equally spaced nearer the horizon (but above the mask
angle).
GPS coordinates calculated when satellites are clustered close together in the
sky suffer from dilution of precision(DOP)
GPS receivers report several components of DOP, including Horizontal Dilution
of Precision (HDOP) and Vertical Dilution of Precision (VDOP). The combination
of these two components of the three-dimensional position is called PDOP -
position dilution of precision.
A key element of GPS mission planning is to identify the time of day when
PDOP is minimized.
 GDOP/PDOP – Geometric/Position Dilution of
Precision

GDOP (geometric dilution of precision) or PDOP
(position dilution of precision) describes the error If the satellites are physically close
caused by the relative position of the GPS together, then you have poor GDOP.
satellites. This lowers the quality of your GPS
The more signals a GPS receiver can positioning potentially by meters.
“see” (spread apart versus close together), the
more precise it can be.

GPS Accuracy: HDOP, PDOP, GDOP & Multipath - GI
S Geography
 DOP Factors
Computed through error propagation
Numbers which when multiplied by the errors
(Table 13.3) give the size of the error expected
with no correction to the ranges based on the
geometry of the observed constellation of
satellites- e.g., if DOP factor is 2, the 2 time
the size of error will be the estimated ranges
for that time and location.
For best possible constellation of satellite, the
average value of HDOP is under 3 and under 6
for PDOP (Table 13.4)

Source: Ghilani, C.D., 2022
How to Improve GPS Accuracy
Two major techniques are:
1. Differential GPS (DGPS):
 A relative positioning technique that employ two GPS receivers. The two receivers must collect data
from the same satellites simultaneously
 The position may be a precise absolute position, or just an approximate position. The relative
position between two receivers can achieve sub-meter accuracy.
 One receiver occupies a base-station (point whose coordinates are precisely known from previous
survey), and the other receiver or receivers (known as rovers) whose positions are unknown.
 By placing a receiver on a station with known position, the pseudorange error in the signal can be
determined.
 With base station and rover relatively close (often less than a kilometer), the pseudorange error at
both base station and rover will have approximately the same magnitude.
 Positional accuracy is generally in the range of 1-10mm with elevation difference accuracies around
5mm.
 DGPS can be done in real time with a radio transmitter, the process is called real-time differential
GPS (RTDGPS).
 How to Improve GPS
Accuracy

2. Satellite-based Augmentation System
(SBAS)
A Satellite-Based Augmentation System
(SBAS) is a regional or global navigation
satellite system that enhances the
accuracy, integrity, and availability of
signals from existing global navigation
satellite systems
The Wide Area Augmentation System https://gisgeography.com/gps-accuracy-hdop-pdop-
gdop-multipath/
(WAAS) has a network of ground tracking
This augmented system broadcasts the corrected error in real
base stations that collect GPS signals and
time along with the GPS signal. This is the principal idea of a
determine range errors. satellite-based augmentation system (SBAS) and can provide sub-
- Errors transmitted to meter GPS accuracy.
geosynchronous satellites that relay
correction to rovers.
GPS
Measurements
Static - receivers are motionless on the Earth during the observation
Kinematic - the receivers are either in periodic or continuous motion
Real Time Kinematic (RTK) – Provide immediate results in the field
DGPS - Simultaneous use of two or more code-based receivers that can
provide positional accuracy within one meter
Global Navigation Satellite
System (GNSS)
What Does Global Navigation Satellite System Mean?
GNSS is a constellation of satellites that provide positioning to
many devices through either autonomous (point) positioning or
differential (relative) positioning.
- Autonomous positioning utilize one GNSS receiver whereas
differential positioning utilizes two or more receivers
simultaneously tracking the same satellites.
Used to determine precise location on the surface of the Earth –
through several known satellite positions and measured
distances between receiver and satellites, the position of the
receiver can be obtained.
Provides global coverage.
GNSS Constellation of Satellites
NAVSTAR, USA (GPS)
- Constellation available is 30 + satellites
GLONASS, Russia
- 24 satellites in the constellation
Beidou, China
- 30 satellites in the constellation
Galileo, European Union
- 30 satellites in the constellation
GPS Vs GNSS
Global Navigation Satellite
System
The initial motivation for a satellite system was for military applications, but it has now progressed to more
extensive civil applications, including the following:
Aviation
Disaster warning and emergency response
Land transportation
Maritime
Mapping and surveying
Monitoring of the environment
Precision agriculture
Natural resources management
Research, such as climate change and ionospheric studies
Wireless networking
Photographic geocoding
Mobile satellite communications
Precise time reference
Military precision-guided munitions
 GPS field log.
(Courtesy of Geomatics, Canada)
Videos
i. GPS Modernization (youtube.com)
ii. How GPS Works Today (youtube.com)
iii.The Navy Navigation Satellite System (1967) (youtube.
com)