Magnetometer
Advanced solution for precise aerial magnetic surveys and subsurface detection

What is a Magnetometer

A magnetic field is the area around a magnet, magnetic object, or an electric charge in which magnetic force is exerted. Earth behaves like a giant magnet.

The two primary characteristics of magnetic fields are their strength (referred to as magnetic flux density or magnetic induction) and direction.

A magnetometer is a device that measures the magnetic field at a point where it is.

Types of Magnetometers

  • Scalar Magnetometers
    Measure only the strength of the magnetic field.
  • Vector Magnetometers
    Measure both the strength and direction of the magnetic field.
Schematic illustration showing Earth’s magnetic field, with labeled magnetic poles and lines

Fig.1 - Schematic illustration showing Earth’s magnetic field

Fun fact
Magnetic compasses, which have existed for thousands of years, also can be treated as “mechanical magnetometers,” which measure the direction of magnetic field only.

Detection Principle

Besides scientific purposes, magnetometers are used to detect objects that create anomalies in the Earth’s magnetic field. These objects typically contain ferrous (iron-containing) materials. When they are surrounded by external magnetic fields (the magnetic field of the Earth first of all), they interact with it and create “anomalies” or changes of magnetic field properties (strength and direction) around the object. On the other hand, “non-magnetic” materials will not do that.

Examples of detectable objects: iron ore deposits, buried utilities, unexploded ordnance (UXO), archaeological artifacts, submarines, and other ferrous metal items.

Underground Pipe Detected Using Magnetometer. An underground pipe exposed in a trench, detected with a magnetometer.

Underground Pipe

Unexploded Ordnance (UXO) Detected Using Magnetometer. Unexploded ordnance (UXO) with a metal casing, detected with a magnetometer.

Landmine in a Metal Case

Metal Barrel Detected Using Magnetometer. A metal barrel, detected with a magnetometer, exposed in a dug trench.

Steel Barrel

Metal Ore Sample Detectable with Magnetometer. A close-up image of a piece of metal ore, an example of objects that can be detected underground using a magnetometer.

Iron Ore

Examples of non-detectable objects: Materials like gold nuggets (yes, it is NOT possible to detect gold nuggets using magnetometers), plastic-cased landmines, plastic barrels, and copper wires, as they do not significantly alter the magnetic field.

Gold Nugget

Landmine in a Plastic Case

Plastic Can

Copper Wire

How it works

By measuring the magnetic field at multiple points across a search area and analyzing the data, magnetometers can identify anomalies where the magnetic field differs from the average level. These anomalies often indicate the presence of magnetic objects hidden beneath the surface.

The most common measurement unit for the magnetic flux density (or magnetic induction) is nanotesla (nT). It’s what you will get in the results of measurements, magnetometer data files, etc.

Typical survey grid planned with UgCS

A screenshot showing a magnetic survey grid planned in UgCS drone flight planning software. The image displays a field with a grid of parallel lines representing the drone’s flight path, planned for a drone equipped with a magnetometer.

Fig.2 - Magnetic Survey Grid Planned in Drone Flight Planning Software UgCS over SPH Engineering’s geophysical sensor Test Range

The result of the magnetic survey with Oasis montaj

Screenshot from Oasis Montaj software showing a magnetic anomaly corresponding to a German WW2 Flam C-250.

Fig.3 - Magnetic map and plot of magnetic field strength along one survey line (data is courtesy of SENSYS GmbH.). The anomaly corresponds to the German WW2 Flam C-250 aerial bomb (without tail) lying 1.5m deep under the surface.

SPH Engineering's offered options

SPH Engineering has a portfolio covering all possible applications of airborne (drone-mounted) magnetometers. More importantly, our magnetic survey solutions have been rigorously tested in diverse environments such as Greenland, Iceland, Papua New Guinea, Israel, Chile, the US, and many European countries, including real UXO searches. We have a collection of best-in-class magnetometers and understand their benefits for particular applications.

Summary of SPH Engineering's offered magnetometers, highlighting key features and recommended applications

SPH Engineering

MagNIMBUS

Geometrics

MagArrow

Sensor

1x or 2x

QuSpin QTFM G2

laser-pumped rubidium total field sensors

1x

FGM3D/75

fluxgate triaxial sensor


2x

FGM3D/75

fluxgate triaxial sensors


5x

FGM3D/75

fluxgate triaxial sensors


2x

MFAM

laser-pumped cesium
total field sensors

Sensor sensitivityVery highHighHighHighVery high
Recommended applications
Geology & mineral exploration
Environmental (abandoned wells, pipes, storage tanks, etc.)
UXO (unexploded ordnance) search
Locating buried infrastructure (metal pipes, shielded cables, and cables under load)
Tramp metal and lost GET (ground engagement tools), pieces of metal detection
Archaeology
Notes for applications

Foldable arm for sensor allows extremely low sensor-ground clearance for UXO search and similar tasks.

Gradiometer configuration simplified data processing and makes possible surveys in presence of external sources of EM fields (power lines etc.)

Very light and compact, ideal for confined and small areas.

Good wind resistance.

Foldable arm for sensor allows extremely low sensor-ground clearance for UXO search and similar tasks.

Very light and compact, ideal for confined and small areas.

Good wind resistance.

Light and compact, ideal for confined and small areas.

Good wind resistance.

Spatial resolution of data is 2 times better than R3.

Wider coverage for single survey lines.

Mounted on suspension cords.

Not convenient for low altitude and rough terrain (mountains etc.).

Bad wind resistance, especially for side wind gusts.

Optimal for the long smooth survey lines when the drone may fly at full speed with minimum changes in speed or direction.

Recommended flight parameters for applications like UXO/tramp metals/GET/utilities search, archaeology, etc.
Distance between survey lines0.5-1 m0.5 - 1 m2 m2.5 m-
Flight altitude*1.5 m AGL1.5 m AGL1 m AGL1 m AGL-
Speed (should be selected according to relief and vegetation)up to 10 m/sup to 10 m/sup to 8 m/sup to 6 m/s-
Other parameters
Live data stream to the ground station
Sampling rate

User configurable:

up to 500 Hz in scalar mode

Good wind resistance.

250 Hz250 Hz200 Hz1000 Hz
Weight

0.7 kg (1 sensor)

1.2 kg (gradiometer)

0.7 kg1 kg2.7 kg1 kg
Recommended drone*

DJI M350 RTK

DJI M300 RTK

Inspired Flight IF800

Inspired Flight IF1200A

or similar

Larger drones like

DJI M600 Pro

IF1200A

or similar

Export restrictions

No

(end-use certificate required)

No

No

No

Yes

(ITAR free version available upon request)

Remarks

For MagNIMBUS and MagDrone R1 flight altitude of 1.5 m AG means sensor-ground clearance of 0.5 m, providing extreme detection capabilities for small ferrous items.

Flight parameters for surveys like mineral exploration vary in very wide extents. Altitude can be up to 50m (above possible obstacles and trees), distance between survey lines usually the same as the altitude. Flight speed can be the maximum safe/economical speed of the drone.

We recommend larger drones for MagArrow because it uses 4x 3m long suspension cords, and for better sensor stability separation between attachment points should be at least 1m. MagArrow can be used with smaller drones like DJI M350 RTK, but its stability will degrade.

Essentials and Applications

Regardless of the application scenario, magnetometers measure the same, but different survey objectives dictate requirements for flight patterns (altitude, survey lines separation) and the optimal type of magnetometer.

Survey objectiveSensor-ground clearanceSurvey lines separationSpeedRecommended magnetometer type
UXO detection and similar environmental applications, including archaeological site surveys0.2 to 5 m, typically <1 m1 mMaximum safe speed according to the terrainMagNIMBUS MagDRONE R4/R3/R1
Geological mapping in general at prospect scale or for detailed mineral exploration with the capability of detecting weakly magnetic targets (e.g., mineral sands strand lines) or distinguishing deeper targets beneath shallow sources of geological noise (e.g., maghemite, rich regolith, laterites, or shallow surficial volcanics)5 to 30 mthe same as sensor/ground clearanceMaximum economical speed of the drone with payloadMagNIMBUS MagArrow
Abandoned cased wells, pipelines, buried services, and waste dump site detection>5 mthe same as sensor/ground clearanceMaximum economical speed of the drone with payloadAny available magnetometer system

Useful Resources

Resources providing an introduction to the basics of aerial magnetic surveys, covering detection ranges and practical low-altitude uses. It’s an excellent guide for a deep and informative overview.

Tell us about your case

And we will tell you how to implement a magnetic survey technology for your application

Benefits of Drone-mounted Magnetometers

There are several standard methods for conducting magnetometer surveys, each with its own benefits and drawbacks. No single method is universally applicable; the appropriate or most suitable approach should be chosen based on the survey target and environmental conditions.

Airborne surveys using manned airplanes or helicopters

+ Very high productivity: hundreds (for helicopters) or even thousands (for airplanes) line kilometers per day
+ Maybe cost-effective in case of large, hard-to-reach areas

- Very expensive
- Requires extremely skilled pilots and personnel
- Applicable for mineral exploration and geological surveys only and for specific tasks like submarine hunting. Search for the small targets (UXO, etc.) is not possible
- Can be dangerous, especially in mountain areas

Terrestrial surveys with back-pack mounted or handheld magnetometers

+ Not qualified personnel can be used for data collection after short training
+ Maybe the only option to collect hi-resolution data in forested areas where it is not possible to use airborne methods (drones)

- Very low productivity
- Hard to use in areas where the surface of the ground is not suitable or safe for walking
- Additional QA (quality assurance) measures may be necessary in case of use of not qualified personnel for data collection

A person conducting a terrestrial survey with a handheld magnetometer

Terrestrial surveys using magnetometer’s array

+ High productivity
+ Good to high data quality

- Applicable only for relatively flat areas without obstacles and vegetation and surfaces with enough bearing capacity
- High cost of the survey system (proportional to the number of sensors in the array)

Terrestrial Survey with Magnetometer Array. A magnetometer array setup for a terrestrial survey, featuring multiple sensors mounted on a wheeled frame.
Courtesy of SENSYS - Magnetometers & Survey Solutions

Airborne survey using UAV

+ High productivity
+ Good to high data quality
+ Data quality is predictable, with minimum influence of human errors or behavior (precision of following of survey lines, etc.)
+ Low to average cost of surveys in terms of price per km
+ The only approach with zero risk for field personnel

- Maybe not cost-effective for very large areas
- Requires qualified personnel for data collection (drone operators)

Airborne Magnetic Survey Using UAV. A drone equipped with a magnetometer conducting an airborne magnetic survey over an open field.

System components

Drone-mounted magnetometer systems include not only drone and magnetometer payload. SPH Engineering supplies end-to-end solutions for every particular application.

Compatible drones: DJI M300/M350/M600, Inspired Flight IF1200A or IF800, Harris Aerial H6, and Wispr Ranger Pro and similar UAV

Drone based magnetometer technology integrated with SkyHub and UgCS by SPH Engineering
Magnetometer payload
Integrated or self-contained magnetometer
+
SkyHub onboard computer
Acts as data logger for magnetometer data and implements True Terrain Following mode
+
Laser or Radar altimeter
Laser or Radar altimeter to fly automatically in terrain-following mode
+
UgCS flight planning software
Ground control software with specialized functions for magnetometer surveys, essential for accurate data collection
+
Data processing software
Data processing software for initial processing (data cleaning, filtering) and to generate deliverables

Tell us more about the place you want to survey and its conditions

And we will help you choose the best option

Data Sets
Case Studies
Frequently Asked Questions
What is the range of a magnetometer?
Scientifically correct answers may surprise you: the range of a magnetometer, or scanning depth, is ZERO.
Do you provide magnetic survey services?
No, SPH Engineering does not provide magnetic survey services. We are a dedicated vendor that supplies the complete system, including all necessary components, training, and support.
In rare cases, we participate in expeditions, such as those involving the search for lost aircraft (like the Greenland expedition and the search for Amelia Earhart in Papua New Guinea). Additionally, we can provide on-site training for our customers. However, we do not offer magnetic survey services.
Do you provide magnetometer data processing services?
Yes, we offer data processing services in limited volumes, primarily to assist our customers in setting up data processing workflows and transferring knowledge to their staff. Please contact us to discuss the details.
Does flight planning for magnetometer surveys have specifics?
Yes, but not so many. UgCS flight planning software has special functions for magnetometer survey support, and specifics are covered in our training courses and articles, i.e. Application | Magnetic and other low altitude surveys »»»
What is the difference between magnetometers and metal detectors?
Magnetometers are passive sensors that measure the magnetic field at the point where the sensor is. The detection principle is based on the analysis of variations of magnetic field (magnetic anomalies) in the survey area.
Metal detectors, or electromagnetic impulse (EMI) metal detectors, are active sensors. They emit electromagnetic impulse, which generates Eddy current in conductive objects below the detector’s coil. These Eddy currents generate “secondary” electromagnetic fields, which can be registered by a detector.
Benefits of magnetometers: they are lightweight and better-suitable for airborne applications. Also, they may detect large targets (like air bombs) at a distance of a few meters.
Benefits of EMI metal detectors: they can detect any conductive items made of copper or similar non-ferrous metals and, in theory, smaller items than magnetometers. But their range is limited by 2 .. 3 diameters of the search coil.
Can landmines be detected with magnetometers?
Magnetometers are capable of detecting a range of items, starting from hand grenades (the estimated sensor-target distance for detecting an object such as the F1 hand grenade is 0.5 m) till big UXO such as aerial bombs at a distance of a few meters.
While magnetometers can detect some types of landmines (for example, M15, M6, TM-62M anti-tank mines; M16, PROM-1, OZM-3, OZM-4, OZM-72 anti-personnel mines and similar types with considerable amounts of ferrous metal), landmines search is not a direct application of magnetometers as they can’t detect most types of modern landmines. That means that the system should never be used to confirm the absence of landmines (and small ordnance) in certain areas, but it can be a valuable asset during a Non-Technical Survey (NTS) or Technical Survey (TS) to confirm the presence of UXO/landmines with a considerable amount of ferrous metals.
Can UXO be detected if flying over vegetation or forest?
Magnetometers can detect some big UXO items at a distance of a few meters, but the detection probability is reduced by the third power of the distance between the magnetometer and the targets.
That makes magnetometers not effective for UXO detection in areas with tall vegetation and trees.
Why do average magnetometer readings vary across different regions?
If we measure the magnetic field around the globe, we will see a very heterogeneous picture (source: World Magnetic Model (WMM))
That world magnetic map has not only scientific value but also allows you to quickly diagnose your airborne magnetometer system. If you collect magnetic data at some reasonable altitude over the ground to exclude local anomalies from subsurface objects, for example, at 100 m, you should get measurements in nT very close to the values from this map. For example, for Latvia, it should be between 51000 and 52000 nT. If you will get measurements far outside of the expected range, your system most probably malfunction.