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The answer depends on what type of magnetic sensor you are speaking of.
One type might be a reed switch. In the presence of a magnetic field the switch changes state, either opened to closed or closed to open. I'd consider this one the simplest type of sensor. Either the field is strong enough to cause the state change or it isn't.
Another type I'd consider to be more of a transducer. According to physics' proof and the ideas of a guy from long ago named Faraday, a changing magnetic field (this field is also said to be in a state of "flux" when changing) in the presence of a conductor will induce a voltage proportional to the rate of change of the field.
Mathematically stated this is written as
e = k do/dt
where e is the voltage induced, k is a constant of proportionality, and do/dt (the derivative of phi, o, with respect to time) is the rate of change of the flux.
(Note: o is supposed to be the Greek letter phi, but I haven't a convenient means of entering it, and I don't remember the ASCII code.)
Anyway, so this e voltage that's developed can be measured with a voltmeter or via an oscilloscope and is proportional to the rate of change of the magnetic field. Rarely would a magnetic field remain constant. Therefore, one can always expect some amount of potential to be developed no matter how small.
However, you may be asking, 'but what about the field itself. How would the field's strength be detected?'
The do/dt in the above equation is the key. Just the same way that o can be differentiated (called "taking the derivative" of) to obtain do/dt, do/dt can be integrated (the opposite/inverse of differentiation) to obtain o. However, it should be understood that there must be a time period involved, because integration is, simply stated, the area under the curve. You can't have an area without a width. Therefore, when integrating we're taking a bunch of infinitessimally small-width rectangles and summing them over a period of time (because time is the independent variable in the above equation and not something else.)
So, leaving the Calculus aside except for the above equation, the way the magnetic field is detected is the voltage e that's developed must then be applied across a load. For example, we could just measure it with a voltmeter, but that voltmeter itself is a load, a very high resistance load. When that load is applied, a current flows due to more physics and the theories of another guy long before television named Ohm (if there is a closed loop for the current to flow in.)
Ohm's Law (actually, I'm pretty sure it's still a theory, but they call it a law) states:
voltage = current x resistance
or
e = i x r
or
The potential, e, developed across a resistance is proportional to the current flowing through the resistance. (Notice that e gets larger as i gets larger?)
Hence, rearranging Ohm's Law to solve for i we have (and I'm going to write the equation downward this time):
e
=
ir
therefore
e
--
r
=
ir
--
r
therefore
i
=
e
--
r
So (saying it like a normal person now) we have
i = e/r
What this says is we can produce a current proportional to the voltage developed by applying that voltage across a load.
Hence, to sense the strength of the magnetic field, we can integrate the rate of change of the flux over time, or, if we're only interested in whether the field is present or not, we can read the voltage developed whenever the field changes. Either way we have sensed the magnetic field.
There's one other way to sense a magnetic field and it's by way of another phenomenon of physics called "The Hall Effect." However, I regret that I don't remember enough about it to explain it very well. In a nutshell, a voltage is developed in the presence of a magnetic field within (usually) a semiconductor material by the magnetic force causing drifting positive charges to go one way and negative charges to go the opposite way thus producing a difference of potential across the material. That difference of potential is called the "Hall voltage" or "Hall emf" (electromagnetic force, voltage). However, with this short explanation I really do not do Edwin Hall (another guy who didn't watch tv) justice. And I'd really appreciate it if someone more knowledgeable will post an update to this answer which does explain it.
What else can I help you with?
What are fluxgate sensors?
Fluxgate sensors are magnetic sensors that measure the intensity and direction of magnetic fields. They are commonly used for compasses, navigation systems, and detecting changes in the Earth's magnetic field. The operation of fluxgate sensors relies on electromagnetic principles to detect and measure magnetic fields accurately.
How do switchable magnets work and what are their applications?
Switchable magnets work by using an external magnetic field to change their magnetic properties, allowing them to be turned on or off. These magnets have applications in various industries, such as in magnetic storage devices, sensors, and medical equipment. They are also used in robotics, automotive systems, and energy generation.
How do machines recognize paper money?
Machines recognize paper money using a combination of sensors, such as optical sensors for reading security features like watermarks and holograms, magnetic sensors for detecting magnetic inks, and infrared sensors to verify the presence of specific features. This information is then compared to a database of known currency features to authenticate the bill.
Are radial magnetic fields measurable?
Yes, radial magnetic fields are measurable using techniques such as magnetic field sensors or magnetometers. These devices can detect and quantify the strength and direction of magnetic fields, including radial ones.
How do meters make use of magnetic fields?
Meters can make use of magnetic fields in devices like electromagnetic flow meters which measure the flow rate of a liquid by applying a magnetic field and detecting the resulting voltage induced when the liquid flows through it. Other meters, like magnetic field sensors, work by measuring changes in magnetic fields to sense the presence, position, or movement of objects or materials.
What are fluxgate sensors?
Fluxgate sensors are magnetic sensors that measure the intensity and direction of magnetic fields. They are commonly used for compasses, navigation systems, and detecting changes in the Earth's magnetic field. The operation of fluxgate sensors relies on electromagnetic principles to detect and measure magnetic fields accurately.
Why would magnetic compass not work in space?
A magnetic compass depends on Earth's magnetic field for orientation. In space, there is no magnetic field to interact with, so a magnetic compass would not be useful for navigation. Other orientation systems, like gyroscopes or star tracking sensors, are used instead in space.
How do switchable magnets work and what are their applications?
Switchable magnets work by using an external magnetic field to change their magnetic properties, allowing them to be turned on or off. These magnets have applications in various industries, such as in magnetic storage devices, sensors, and medical equipment. They are also used in robotics, automotive systems, and energy generation.
When they might of be used?
magnetic sensors and state where they might be used.
Are crankshaft position sensors magnetic?
Some are.Some are.
Where do you use magnetic field?
In a magnetic compass, electric motors, security system sensors and a whole lot more.
What are the magnetic sensors?
The simplest detection of a magnetic field is done by another magnet. Or by an apparatus such as a Fluxgate magnetometer or similar.
What sort of material do you need to detect a magnetic field?
You can detect a magnetic field using materials such as magnetometers or magnetic sensors. These devices typically consist of magnetic materials like nickel, iron, or alloys that change their electrical properties in the presence of a magnetic field, allowing for detection and measurement. Additionally, sensors like Hall effect sensors or magnetoresistive sensors can also be used to detect magnetic fields by measuring variations in electrical resistance or voltage caused by the field.
How do electric rings work and what are their applications in modern technology?
Electric rings work by generating a magnetic field when an electric current passes through them. This magnetic field can be used to create motion or induce electrical currents in nearby objects. In modern technology, electric rings are commonly used in electric motors, transformers, and generators. They are also used in various sensors, such as inductive proximity sensors and metal detectors.
How do machines recognize paper money?
Machines recognize paper money using a combination of sensors, such as optical sensors for reading security features like watermarks and holograms, magnetic sensors for detecting magnetic inks, and infrared sensors to verify the presence of specific features. This information is then compared to a database of known currency features to authenticate the bill.
What sensors does the robot have?
The sensors that an engineer puts on a robot are entirely dependent upon the functions that the engineer perceives that the the robot will be called upon to perform. Some, but not all, of the sensors may be: proximity sensors, pressure sensors, light sensors, magnetic sensors, a camera, temperature sensors, accelerometer, speed sensor... The question isn't, "what sensors does a robot have", but rather, "what sensors does the engineer think that the robot should have?"
What instrument measures magnetic flux?
Many devices can measure magnetic flux: Hall effect sensors, fluxgates, magnetoresistive devices, etc.
