Surveying Capter-5: GPS Survey Methods

GPS Survey Methods

Contains:

Single Point or Point Vs Relative, Static Vs Kinematic, Real time Vs Post mission, Practical GPS survey field procedures: Code- and Carrier-based positioning, Accuracy and recording time, Preparation of GPS surveys: Setting up an observation plan, Practical aspects of field observations, Observation strategies, Network design

1.       GPS Positioning modes:

Point positioning: It is an absolute mode of positioning, in which a single point has well defined co-ordinates with respect to pre-defined global reference system.

Relative positioning: In this mode of positioning observer takes a reference from different point. The co-ordinates of a point are defined with respect to a known co-ordinate point. Relative positioning is also known as base line determination in GPS surveying. It is a differential type of positioning.

Static positioning: coordinates of a stationary point in absolute or relative mode.

Kinematic positioning: coordinates of a moving point in absolute or relative mode. Relative positioning can be taken either in real time or post mission modes.

2.       Real time Vs Post mission:

Real time mode of positioning somewhat related to the near line site conditions, whereas post mission mode allows users to get sub meter positioning up to 300km and mostly used for GIS applications.

Real time processing:

A.      Positions are computed almost instantaneously, on site. No post processing is required and positioning results are instantly available. There are two modes for such positioning- real time code RT-DGPS (code based) and real time phase RTK (phase based).

B.      It needs a data link to transmit corrections from a monitor receiver at a known point to rover receiver at unknown point

Post-mission processing:

A.      GPS data is combined and reduced after all data collection has been completed.

B.      It requires post processing of combination of data from all receivers after an observation period.

3.       Positioning using GPS

Absolute positioning:  A single passive receiver is used at a one station location to collect the data from multi-satellites in order to determine the station location. It is not useful in precise GPS surveying due to less accurate data received, however it is most widely used in military and commercial GPS positioning system for real time navigation and location determination. The accuracies of poisoning is manly dependent on the user’s authorization. GPS point positioning is also known as stand-alone or autonomous type of positioning which involves a single GPS receiver.  It can be determined by the carrier-phase range measurements or code range measurements. GPS receiver tracks at a time more than 4 satellites to determine its own position coordinates.

A standard Positioning Services SPS) can achieve a real time positional accuracies of 25m without selective availability. The lower level accuracies using SPS is due to intentional degradation of GPS signal by the selective availability. The Precise Positioning Services (PPS) user with a receiver capable of tracking P-code, can a decryption device to achieve a point positional accuracy in the range of 10-12m with a single frequency receive. To get accuracies less than and equal to 1m, special equipment are required with post processing techniques.

Absolute positioning can be sub-divided into following categories;

1.       Absolute positioning using carrier phase

2.       Absolute positioning using C/A-code (pseudo-range)

Absolute positioning using carrier phase

A GPS receiver which is capable of receiving both the C/A-code and carrier-phase is used to collect the positional information. By using broadcast ephemeris, the user is able to use pseudo-range values in real time to determine absolute point positions with an accuracy of 3m in the best conditions and 25 m in the worst condition. Post processing technique can be used to enhance the accuracy level which can be raise up to sub-meter level in best condition and 15m in worst conditions.

Absolute positioning using C/A-code (pseudo-range)

It is used for navigation purpose. When a GPS user perform a navigation solution using C/A-code than an approximate range or pseudo range is measured. Satellite position and range are very important parameters which should be known when determining the precise location. Application of pseudo range is to measure approximate distance between GPS antenna and satellite by correlation of satellite transmitted code and reference code created by receiver, without any error correction in synchronization between the clock of the transmitter and that of the receiver.  The traveled distance by a signal can be measured by multiplying the velocity of transmission of its satellite to elapsed time of transmission, with the tropospheric and ionospheric effects are accounted. The accuracy of positioning is a function of range measurement, and geometry of satellite. The geometrical magnification of uncertainty in a GPS point positioning can be describe by Dilution of Precision (DOP). For improvement of GPS range accuracy repeated and redundant range observation must be taken, however DOP remains same.

In a static mode, range measurement may be continuously re-measured over varying orbital locations of satellites. Different satellites orbits cause different positional intersection geometry.

At least four pseudo-range observations must be taken to resolve a 3D GPS position. Only three pseudo-range observations are required for 2D GPS position. In practice more than four observation are taken. To resolve the clock biases contained in both satellite and ground receiver, more pseudo ranges are needed.

Accuracy and recording time:

Accuracy of GPS observations can be varying from some meter level to sub centimeter level, depending upon the method of GPS survey adopted and capability of GPS receiver used, and also for the type of uses whether it is used for military purpose or civilian use, accuracy differs.

Lower the recording time, higher will be the data recorded which will boost the accuracy of observation so generally it is kept 1seconds. But lower recording time increases the memory uses also hence some time it causes trouble,

The main factors affecting the accuracy of GPS observation can be listed as below;

1.      Biases and measurement errors

2.      Mode of positioning whether absolute or differential positioning mode

3.      Geometry of satellite and receiver

4.      Pre and post processing algorithms, operational modes, and others

Accuracy and precision: it is referred to the closeness of observation to the real value. Precision referred to the closeness of repeated observation to the mean value of a group of observation sample.

Biases: These are the systematic errors, which are responsible for the change in the true measurements from the observed value by a constant amount, in a predictable and systematic manner.

DOP (Dilution of Precision); in case of navigation application, the effect of satellite configuration geometry is expressed by DOP. It is a ratio of the positioning accuracy to the measurement accuracy.

Biases and measurement errors: All GPS measurements (pseudo range, carrier phase, Doppler frequency) are very sensitive to the biases and errors, their combined effect alters the positioning results. For high accuracy work biases must be accounted in processing step of GPS data processing. Sources of biases may be grouped depending upon their characteristics such as magnitude, periodicity, satellite and receiver dependencies. Manly biases can introduced by physical bases such as atmospheric effects and signal propagation, but they can also introduced in the data processing stage due to poor knowledge of fixed constants (like satellite orbit, station coordinates, velocity of light) to the user. By considering errors we can consider the biases, which are correlated in space and time. .

Mode of positioning: Both the mode of positioning, absolute or point positioning and relative positioning, are fundamental to consideration of error /biases in GPS results and the datum to which the GPS results relate. Point positioning with respect to well defined coordinate system (WGS84 Cartesian reference system). This coordinate system is direct realized to the monitoring station coordinates and subsequently transferred to the users via the coordinates of the GPS satellite. As the satellite coordinates are the key of computation of user position, any error or biases in these coordinates will directly affects the accuracy and precision of results.

Higher accuracies can be obtained by the relative positioning mode using the two receiver at different positions, tracing the same satellites, because many errors will affect the absolute positioning of two GPS receivers almost to the same extent which will be subtracted in differential or relative positioning mode.

Geometry of satellite and receiver: Accuracy of satellite measurements is also a function of satellite-receiver geometry. Lesser the DOP, value higher will be the accuracy of GPS observations and errors associated with measurements are not so much amplified.  Higher values of DOP makes the position a point too much unreliable, called outage. DOP varies with time and geography of an area, although for same area it is same in ideal condition. DOP plays a vital role in point positioning, although its role is limited in the relative positioning.

Pre and post processing algorithms, operational modes, and others: accuracy is also dependent on

a.       Whether the user is stationary or moving condition, repeated observations are taken in stationary operation of receiver which gives higher accuracy.

b.      Whether the results are in real time or post processing, post processing improves the accuracy of results by removing or lowering the errors associated.

c.       The level of measurement noise considerably affects the accuracy.

d.      Degree of redundancy in measurements

e.       Algorithm type used in processing of data

Preparation of GPS surveys

Setting up an observation plan: As long as the GPS system was not yet complete, a pre-computation of coverage was an indispensable preparatory step in project planning. With the system completely deployed in 1995, sufficient satellites are visible above the horizon at any time; hence field campaigns can be planned independently of the constellation. For analysis purposes, and for kinematic observations, a pre-computation of the satellite constellation can still be of importance.

These so-called ALERT-lists can be computed with data from the satellite almanac. Almanac data, that is, low accuracy orbit data for all available satellites, are transmitted in the fourth and fifth subframes of the navigation message. These subframes have 25 “pages” each 30 seconds long, so that the complete almanac information can be read in 12.5 minutes.

With the aid of the almanac data, satellite positions can be precomputed over several months with sufficient accuracy for planning purposes. One must, however, occasionally expect larger orbit maneuvers, so that a regular check of the almanac data is recommended. With the almanac data, visibility diagrams and PDOP values can be generated. Most manufacturers provides suitable software packages (mission planning software) on a PC basis. The almanac data are available from various internet sources,

Practical aspects of field observations:

Firs essential step which should be considered by a GPS surveyor is local reconnaissance in advance for taking successful observations on field.

The site selection is a prime concerned for surveyor, the visibility between two stations must be there for setting out of a base line and site should be accessible for surveyor and vehicles along them.

It should be kept in mind as a general rule, that a free line of sight down to the horizon must be created in all directions.

In a forested areas or near buildings, a satellite visibility diagram ( sky plot, cf, fig.2) helps in the site selection.

If the site is kept same for later observation purpose, with the different satellite constellation, it is recommended that horizon kept open at least down to a 10⁰   elevation angle. For price surveying work, height determination is advantageous for observations down to 5⁰ for price height.

If there is any obstructions at the site, they must be documented, when reconnaissance survey is done in reconnaissance sheet in a shadow diagram.

The GPS surveying technique is far better than the conventional surveying technique such as triangulation, the selection of GCP’s is more flexible than classical triangulation approach. It permits somewhat flexibility in selection and requirement of GCP’s. The ground control points need not to be inter-visible so there is no requirement of setting them on topographic elevations or towers but only they should be minimally obstructed and easily accessible.

The selection of GCPs must be avoided (or not suitable) near the high buildings, power lines, towers, transmitting antennas etc because of the introduction of multipath errors.

Receiver antennas must be kept very high in wooded areas, can be mounted on light masts.

Centering and plumbing of GPS rover must be done precisely so that GPS measurement evaluation is accurate and required accuracy can be achieved, however in case of non-centeric observation  required accuracy diminishes. Note that eccentricity calculation have to be done in 3D space

In case of Follow-up survey with electronic tacheometers, GCPs should be selected so a free sight is available to nearby station mark or an inter-visibility lie between two GCPs installed a few hundred meters away.

Generally survey station are decided by the mapping and responsible surveying authorities. For surveys seeking for high accuracy, the installation of stations must be done on stable ground possibly on rock or concrete blocks.

The station mark can be used as exact vertical reference so sufficient depth of foundation must be provided.

All essential information should be documented in a reconnaissance sheet, possible elements are,

1.      Station name and identification code

2.      Description of site

3.      Approximate coordinates and height

4.      Accessibility(car, road condition, walking distance)

5.      Necessary antenna height(tripod, mast)

6.      Orientation marks

7.      Shadow diagram

It is essential to check the batteries of receiver and rover every day, although power supply is not a issue, because of long lasting batteries in these days.

Newer version of receiver are so designed that no requirement of skilled workers, however for standard operation work and for precision skills are necessary. The personnel operating the GPS, 

should be capable of following:

1.      Mounting the tripod on the station mark

2.      Measuring the antenna height

3.      Controlling the receiver operation

4.      Complete the work according to a given time

5.      Run the station control sheet

6.      Measuring additional data if required

After completion of survey, GPS data must be downloaded and stored in an appropriate recording device for further analyzing and processing of data. Data download can be done once or twice a day, depending upon memory capacity and amount of data stored. Modern receiver hav built in solid state memories or plug in memory cards.

Observation strategies: Two observation strategies can be follow in any GPS surveying;

1.      Some of the main sites should observe during at least one 5 to 7 hours session during one single working day. Whereas remaining sites may observed in quasi-continuous manner.

2.      All the base lines may be chosen so as to minimize their length, to minimize common observations between stations and to avoid receiver and antenna type mixing.

3.      Generally, the collected GPS data were processed on the daily basis and cleaned for cycle slips automatically in most cases and manually whenever required in order to ensure the reliability of the results (Tomae and Tsagannidou, 1998).

(Reference:The Adria Microplate: GPS Geodesy, Tectonics, and Hazard... Edited By Nicolas Pinter)

Network design: It a most important aspect of surveying. The final network design or project design refer to a compromise in the technical requirements as well as economics, which is carried out within the framework of explicit recommended practices for GPS surveys.

The surveyor must kept in mind when designing a network;

1.      Definition of network, it means size and shape of network, required GCPs, number of stations and spacing between them, inter-visibility if any requirement is there.

2.      Spacing of exiting known stations

3.      Accuracy requirements and standards 

(Reference:  Global Navigation Satellite System By Rao)

Generally GPS stations forms a cluster of points around the project area for example roads, dams etc.

This clustering provides the surveyor, a good traditional geodetic control over an area but generally main stations marks are evenly spaced, and located at prominent locations, such as hill top, so that inter-visibility can be assured between two station marks. Extra control over nearby geodetic area is not required in the GPS surveys. Hence the Importance of even spacing of stations and selection on the basis of terrain profile, no longer plays a vital role.

Once the number of total station decided, and also the approximate location of these station, some of the important points must be consider;

1.      There should be some inter-visible stations to the azimuth in starting of survey without disturbing the original network design.

2.      Depending upon the terrain, some reference marks must be set up. The distance may be taken in the range of couple of hundred.

3.      Some existing stations if there in site area, may be included in survey which can be used to ensure datum definition or calibration of GPS heights.