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Hi all,
We have now successfully designed and built a Proton Magnetometer instrument (See under Magnetometer forum, the MarkIVb PPM project).
This device is now mature after 6 years of hard work and we are looking for a new challenging R&D project.
Before this project, back in 2003, we (a team of two) have designed and built the prototype of a digital PI metal detector with magnetic/non-magnetic discrimination capabilities. My aim at that time was to contradict those who claimed that this was impossible. This project produced a working prototype but my partner let me down and the project died away.
In 2004, I have built a simple DC resistivity measurement device to be used the area of our archaeological field.
This simple device worked well to show man-made underground structures like fire pits, wells and wall foundations but the operation was slow, boring and error-prone even with several operators.
In 2009, I conducted a new R&D project over the FDEM technology to replace this device for the same usage.
This technology is very delicate to setup because the receiving and measurement process is executed DURING the transmitting frequency. In spite of the bucking coil, it was very difficult to get good SNR.
The frame on which the various coils are fixed had to be both solid and light to avoid the distortion due to vibrations during the operations.
After a large number of lab tests, I have started the real field tests but these did not give satisfactory results compared to the results I got from the DC resistivity device.
Now, I want to start a new R&D project based on the TDEM technology to measure the relative conductivity of the underground soil and possibly to detect as well any metallic targets (made of magnetic material or not) buried there.
The processes used in this technology are very comparable to the ones used in my previous digital PI project. Thus, I could reuse part of my past experience on that subject.
Unlike the FDEM technology, the TDEM data capture process is executed AFTER each transmitting pulse making it easier to reduce the noise generated by the transmiting coil.
A TDEM device differs from a PI detector with several characteristics:
- Most PI systems use the same coil for transmitting pulses and listening to the induced signal while TDEM systems use separate coils.
- PI systems detect the presence of potential targets by measuring the difference of voltage decay between a pre-captured ground signal and the most current signal capture and aurally and visually signal the results in real-time based on a programmable threshold.
They measures this voltage at a single time slot of the decay slope.
TDEM systems capture and record the decaying voltage at multiple time slots (> 20) during the early decay duration and also during the late decay time. We shall see later how these results are used in post-processing.
- The results of the surveys using TDEM systems are not so much displayed in real-time but rather, are studied in the back office using a number of post-processing tasks.
- Surveys made with TDEM systems (like those made with a magnetometer) are either made under GPS control or at least, as a number of parallel grid lines over the area to be surveyed. This allows to display the results of the survey as 2D or 3D colored scale plots. These plots are then used to make the real target detection or to evaluate the regions of the surveyed area which are useful for the specific purpose.
- TDEM systems inject a larger electromagnetic energy in the ground in order to 'view' deeper ground layers and thus, use larger coils and a larger transmitting current.
The best-known (and now already old) commercial device reference of that TDEM technology is the EM61 instrument from Geonics.
The TDEM system is made of several functional modules, each applied as a separate hardware module and its associated firmware/software code.
- Pulse Transmitter module and it coil
- Receiving module and its coil(s)
- Signal Data Processing, display and storage module
- Post-processing program(s)
I want to start a discussion thread on this forum on that subject with anyone interested in that technology and wishing to share his experience in any aspect of the project.
There will be discussions and work on the subjects of mechanical structure design, electronic design and digital signal processing.
I bring to that project my background as professional data processing and telecom engineer and my long practical experience with digital signal processing using powerful ARM-based microprocessors.
Welcome to active participators and even to simple visitors!!
Willy Bayot
We have now successfully designed and built a Proton Magnetometer instrument (See under Magnetometer forum, the MarkIVb PPM project).
This device is now mature after 6 years of hard work and we are looking for a new challenging R&D project.
Before this project, back in 2003, we (a team of two) have designed and built the prototype of a digital PI metal detector with magnetic/non-magnetic discrimination capabilities. My aim at that time was to contradict those who claimed that this was impossible. This project produced a working prototype but my partner let me down and the project died away.
In 2004, I have built a simple DC resistivity measurement device to be used the area of our archaeological field.
This simple device worked well to show man-made underground structures like fire pits, wells and wall foundations but the operation was slow, boring and error-prone even with several operators.
In 2009, I conducted a new R&D project over the FDEM technology to replace this device for the same usage.
This technology is very delicate to setup because the receiving and measurement process is executed DURING the transmitting frequency. In spite of the bucking coil, it was very difficult to get good SNR.
The frame on which the various coils are fixed had to be both solid and light to avoid the distortion due to vibrations during the operations.
After a large number of lab tests, I have started the real field tests but these did not give satisfactory results compared to the results I got from the DC resistivity device.
Now, I want to start a new R&D project based on the TDEM technology to measure the relative conductivity of the underground soil and possibly to detect as well any metallic targets (made of magnetic material or not) buried there.
The processes used in this technology are very comparable to the ones used in my previous digital PI project. Thus, I could reuse part of my past experience on that subject.
Unlike the FDEM technology, the TDEM data capture process is executed AFTER each transmitting pulse making it easier to reduce the noise generated by the transmiting coil.
A TDEM device differs from a PI detector with several characteristics:
- Most PI systems use the same coil for transmitting pulses and listening to the induced signal while TDEM systems use separate coils.
- PI systems detect the presence of potential targets by measuring the difference of voltage decay between a pre-captured ground signal and the most current signal capture and aurally and visually signal the results in real-time based on a programmable threshold.
They measures this voltage at a single time slot of the decay slope.
TDEM systems capture and record the decaying voltage at multiple time slots (> 20) during the early decay duration and also during the late decay time. We shall see later how these results are used in post-processing.
- The results of the surveys using TDEM systems are not so much displayed in real-time but rather, are studied in the back office using a number of post-processing tasks.
- Surveys made with TDEM systems (like those made with a magnetometer) are either made under GPS control or at least, as a number of parallel grid lines over the area to be surveyed. This allows to display the results of the survey as 2D or 3D colored scale plots. These plots are then used to make the real target detection or to evaluate the regions of the surveyed area which are useful for the specific purpose.
- TDEM systems inject a larger electromagnetic energy in the ground in order to 'view' deeper ground layers and thus, use larger coils and a larger transmitting current.
The best-known (and now already old) commercial device reference of that TDEM technology is the EM61 instrument from Geonics.
The TDEM system is made of several functional modules, each applied as a separate hardware module and its associated firmware/software code.
- Pulse Transmitter module and it coil
- Receiving module and its coil(s)
- Signal Data Processing, display and storage module
- Post-processing program(s)
I want to start a discussion thread on this forum on that subject with anyone interested in that technology and wishing to share his experience in any aspect of the project.
There will be discussions and work on the subjects of mechanical structure design, electronic design and digital signal processing.
I bring to that project my background as professional data processing and telecom engineer and my long practical experience with digital signal processing using powerful ARM-based microprocessors.
Welcome to active participators and even to simple visitors!!
Willy Bayot
Tomorrow I'll write more about it !
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