Electromagnetic Methods (EM) Measurement of varying electromagnetic fields Induced by transmitter antennas, recorded by receiver antennas Alternative measurement.

Slides:

Advertisements

Similar presentations

Stratagem EH4 Geometrics, Inc.

Advertisements

Electromagnetic Waves (Optional Unit)

Stratagem EH4 Field Evaluation of Data Quality.

Chapter 32C - Electromagnetic Waves (Optional Unit)

Alternating Current Circuits and Electromagnetic Waves

ENE 325 Electromagnetic Fields and Waves Lecture 10 Time-Varying Fields and Maxwell’s Equations.

San Jose, California USA

Imaging a Fault with Magnetotellurics By Peter Winther.

electromagnetic method

Chapter 29 Continued-Chapter 31- Chapter EMF Induced in a Moving Conductor Example 29-8: Force on the rod. To make the rod move to the right.

UTAM 2004 Travis Crosby. UTAM 2004 Travis Crosby Very Low Frequency EM Surveys for the Purpose of Augmenting for the Purpose of Augmenting Near-Surface.

Inversion of Z-Axis Tipper Electromagnetic (Z-TEM)‏ Data The UBC Geophysical Inversion Facility Elliot Holtham and Douglas Oldenburg.

LOGO EM-38 INCA 2008 International Course on ArchaeoGeophysics 20 July-5 August 2008 in İznik, Turkey Ertan Pekşen.

Naval Weapons Systems Energy Fundamentals Learning Objectives  Comprehend basic communication theory, electromagnetic (EM) wave theory  Comprehend.

Electromagnetic Wave Theory

Antennas. Free Charge  A free charge has a constant electric field and no magnetic field.  No waves are produced. No radiationNo radiation  A charge.

Module No. 18 Electrical Methods

Basics in Magnetism Electromagnetism Force on a Current-Carrying Wire EM Induction Transformer Generators Electric Motors ELECTROMAGNETISM.

AERIALS AND RADIO FREQUENCY PROPAGATION By Farhan Saeed.

IGCSE PHYSICS Generators and Transformers

الإستـكـشاف الـكـهـربائـي والـكـهـرومغناطيسي

C H A P T E R 22 Electromagnetic Induction.

1 Things to know (a)deduce from Faraday’s experiments on electromagnetic induction or other appropriate experiments: (i) that a changing magnetic field.

1 Antennas: from Theory to Practice 1. Basics of Electromagnetics Yi HUANG Department of Electrical Engineering & Electronics The University of Liverpool.

Eddy Current Testing This method is widely used to detect surface flaws, to measure thin walls from one surface only, to measure thin coatings and in some.

Radio Communication SL – Option F.1. Radio communication includes any form of communication that uses radio (EM) waves to transfer information –TV, mobile.

Advanced Radio and Radar Part 1 Communicating. Introduction Communication may be defined as “the exchange of information” and as such is a two-way process.

Chapter 9 Electromagnetic Waves. 9.2 ELECTROMAGNETIC WAVES.

Magnetism, Electromagnetism, & Electromagnetic Induction

Electromagnetic wave equations: dielectric without dispersion Section 75.

Book Reference : Pages To understand how we generate alternating current (A.C.) 2.To begin to appreciate some of the advantages of A.C.

“Frequency domain” EM“Time domain” EM. Measurement of signal decay – sample the decaying amplitudes in a number of time windows, or “channels” As the.

PRESENTATION ON TRANSFORMER PREPARED BY: VRUNDA RANA( ) KRIMA PATEL( ) NIKITA THAKKAR( ) ELEMENTS OF ELECTRICAL ENGINEERING.

Generator and Transformer. Moving Conductor If a straight conductor is moved in a path perpendicular to a magnetic field, a current is induced in the.

ELECTROMAGNETIC INDUCTION

Chapter 21 Electromagnetic Waves. General Physics Exam II Curve: +30.

UPenn NROTC Unit, dtd Fall 2004 Naval Weapons Systems Energy Fundamentals.

 Prepared by:  Jignesh k patel  Roll no:17  1 st year B.E, Electrical  Enroll : Guided by: Latesh Patel Piyush Patel Laxmi Institute of.

Production and Control of High Voltage

References Blome, C.D., Faith, J.R., Smith, B.D., Collins, E.W., Clark, A.R., and Ozuna, G.B [2005] Geologic mapping of the Edwards and Trinity aquifer.

Unit 9: Part 2 Electromagnetic Induction and Waves.

Introducing the Stratagem EH4. Stratagem EH4 Hybrid-Source Magnetotellurics Frequency range of 10 Hz to 90k Hz Approx. depth of investigation from 5m.

Electromagnetic Methods (EM) Basic principle: Transmitter current (Ip) generates primary field (P), which generates ground emf, leading to subsurface “eddy”

Lecture 19 VLF GPR. Phase Phasor In phase cos(wt) Advanced in phase cos(wt+Ф) Ф.

Tuesday April 19, PHYS , Dr. Andrew Brandt PHYS 1444 – Section 02 Lecture #18 Tuesday April 19, 2011 Dr. Andrew Brandt Chapter 29 Lenz Law.

© Houghton Mifflin Harcourt Publishing Company Preview Objectives Electromagnetic Induction Characteristics of Induced Current Sample Problem Chapter 20.

Chapter 5 Electromagnetic Waves. 1. Introduction: Maxwell’s equations  Electricity and magnetism were originally thought to be unrelated  in 1865, James.

“Frequency domain” EM Response of frequency domain EM over a good conductor.

Faraday’s Law of Induction Magnetic flux  = A B cos   B A A changing magnetic flux generates an induced voltage (emf = electromotive force) V = [emf]

PHYSICS – Electromagnetic effects (1). LEARNING OBJECTIVES Core Show understanding that a conductor moving across a magnetic field or a changing magnetic.

SACE Stage 2 Physics Light and Matter Electromagnetic Waves.

Practice Problems A horizontal wire is moving vertically upwards in a horizontal magnetic field of strength tesla which is perpendicular to the.

Magnetism, Electromagnetism, & Electromagnetic Induction.

 Electromagnetic Induction – The production of an emf (the energy per unit charge supplied by a source of electric current) in a conducting circuit by.

AC Current An AC circuit consists of a combination of circuit elements and an AC generator or source The output of an AC generator is sinusoidal and varies.

Home Magnet Fields 5.14 Magnetic Flux Electromagnetic Induction 5.16 Magnetic Effect of a Steady Current.

Radio Communication SL/HL – Option F.1. Radio communication includes any form of communication that uses radio (EM) waves to transfer information –TV,

Magnetism, Electromagnetism, & Electromagnetic Induction

Electromagnetic Methods (EM)

Electromagnetic Waves

Magnetism, Electromagnetism, & Electromagnetic Induction

Induced Voltages and Inductance

Motors and Generators Physics 12 Adv.

Transformers. Transformer An A.C. device used to change high voltage low current A.C. into low voltage high current A.C. and vice-versa without changing.

MAGNETISM AND ITS USES Producing Electric Current

ELECTROMAGNETISM.

Wireless Communications Chapter 4

Magnetism, Electromagnetism, & Electromagnetic Induction

Presentation transcript:

Electromagnetic Methods (EM) Measurement of varying electromagnetic fields Induced by transmitter antennas, recorded by receiver antennas Alternative measurement of subsurface conductivity Advantage is no contact electrodes are required EM surveys are faster, and can be carried out from aircraft Useful in a wide range of applications: –Mineral prospecting –Mapping of faults, shear zones –Detection/location of underground pipes, cables –Mapping of conductive contaminants –Mapping of (conductive) clays in agricultural studies

Electromagnetic Methods (EM) Basic principle: Transmitter current (Ip) generates primary field (P), which generates ground emf, leading to subsurface “eddy” currents. Subsurface eddy currents then generate a secondary field (S), finally both P and S are measured by the receiver.

Sources of time-varying EM fields Natural sources (“Magneto-telluric fields”, or MT) Interaction of solar wind with ionosphere From Hz, up to 20 kHz Low MT frequencies (.001 Hz to 1 Hz) used to investigate upper mantle and lower crust “Audio-magnetotelluric” (AMT) (1-20 kHz) to investigate to 1 – 2 km depth Good at detecting/resolving conductive layers Poor where shallow section is very conductive

Sources of time-varying EM fields Controlled MT source: Magnetotelluric signal is weak at certain frequencies, no control on direction Controlled source AMT (CSAMT) uses electric field bipolar transmitter, 10 m to 30 m in length

Sources of time-varying EM fields Controlled MT source:

Sources of time-varying EM fields “VLF” systems: Source is provided by the US military for communication channels “Very Low Frequency” is actually 15 – 25 kHz (these are high frequencies in geophysical EM) VLF transmitters are located around the world Consist of long, vertical wire carrying AC current Signal from several stations is detectable in most places around the world Local variations in conductivity change the local orientation of the VLF field

VLF systems Primary field, P is horizontal where a conductor is present this changes (“tilts”) the total field (P + S) tilt angle survey will “crossover” over a conductor Facing the transmitterSchematic view

VLF systems Example of a tilt-angle survey

Sources of time-varying EM fields Controlled source systems Time-varying primary EM fields generated by currents in a transmitter loop Receiver coil is physically separated 1 m – several hundred metres Reference signal provided to receiver by cable link Ground systems, airborne systems differ only in scale, principles are the same

Sources of time-varying EM fields

EM theory: basic quantities  - Dielectric permittivity

EM theory: time varying relationships Time varying terms (these were assumed zero in the earlier part of this course)

EM theory: time varying relationships

Substituting: Basic equations for propagation of EM fields

Notes on complex numbers … see course web pages, or your Math textbook

Complex numbers

Because: Therefore:

Complex numbers

Multiplication: Division:

Complex numbers