1. Field
The embodiments discussed herein are directed to a magnetic effects sensor, a resistor and a method of implementing same.
2. Description of the Related Art
Generally, in existing sensing technologies such as induction sensing a finite conductance (to support an eddy current) is essential. The finite conductance requirement presents a problem in induction sensing and other similar sensors because in some situations, conductive nature (conductive metal content) is decreased to the point where there are no currents to sense. For example, dry sand (or other similar medium) is particularly challenging for induction sensing because the eddy current signal contrast from the void created by an implanted, plastic case mine may near zero to where the plastic mine looks like non-conductive sand. Further, sensing of objects that do not have metal content may be necessary.
Attempts have been made to improve range of sensing. However, range of existing sensing including that of induction sensing is limited.
Although various types of sensor technologies are available, there is a need for a sensor technology that is enabled to detect objects and addresses problems associated with existing sensing technologies including induction sensing.
It is an aspect of the embodiments discussed herein to provide a sensor and method thereof for sensing an object possessing magnetic and conductive properties including based on how the object influences an impedance of a magnetic coil and a circuit that includes the coil.
The above aspects can be attained by a system having an adjustable precision variable resistor that can be under automatic control to maintain or stabilize a bridge circuit against resistive drifts away from null.
These together with other aspects and advantages which will be subsequently apparent, reside in the details of construction and operation as more fully hereinafter described and claimed, reference being had to the accompanying drawings forming a part hereof, wherein like numerals refer to like parts throughout.
Reference will now be made in detail to the present embodiments discussed herein, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. The embodiments are described below to explain the disclosed system and method by referring to the figures. It will nevertheless be understood that no limitation of the scope is thereby intended, such alterations and further modifications in the illustrated device, and such further applications of the principles as illustrated therein being contemplated as would normally occur to one skilled in the art to which the embodiments relate.
The embodiments have been described with respect to a magnetic effects sensor and method of implementing same.
Magnetic effects sensor (MES) is new sensor technology; and is different from an induction sensor. The heart of the MES is a passive reactance bridge whose response is influenced by the electrical-magnetic properties of the medium permeated by magnetic field of its coil. A finite conductance (to support an eddy current) is essential for induction sensing, but it is not essential to the MES. This finite conductance requirement is the weakness in induction sensing because the (conductive) metal content of landmines, for example, is decreasing to where there are no eddy currents to sense. For example, dry sand (like in Iraq) is particularly challenging for induction sensing because the eddy current signal contrast from the void created by the implanted, plastic case mine nears zero to where the plastic mine looks like non-conductive sand. The information produced by the MES is very different from that of an induction sensor; and it has detected plastics and nonconductive ceramics from their permeability (magnetic polarizability) which materials are undetectable with an induction sensor.
The MES exploits the fact that the resistance and inductance of an electrical coil depends on the properties of the surrounding space that are permeated by the magnetic flux from the coil. A nulled, AC reactance bridge circuit (incorporating a coil) provides the best known way to exploit this impedance dependence to sense and discriminate objects presented to the coil from the bridge imbalance signal.
As is set forth herein, one advantage provided by this new sensor over existing magnetic sensors is its ability to cancel out ambient magnetic effect clutter in the bridge nulling procedure, which helps us discriminate the occulted objects of interest. Additionally, the circuit provides signals and signal references that allow us to separate the change in coil resistance from the change in coil inductance as a function of frequency. The increase in coil resistance is caused by resistive losses of the eddy currents induced in permeated objects. The change in inductance is caused by induced magnetic polarization in permeated objects and the attendant diamagnetic field of any eddy current in conductive objects. The resistive and inductive signals as a function of frequency are used to discriminate sought objects presented to the coil.
According to an embodiment, the MES detects and discriminates occulted objects including in close proximity to the sensor. Exploiting the complexity of magnetic effects data with various signal filtering alternatives, the MES can be used as a cueing/discrimination sensor for buried targets, or as a discrimination sensor for suspicious targets above ground. For example, the MES can detect and discriminate landmines, artillery shells, improvised explosive devices (IEDs), and bulk explosives of various chemical compositions that are devised by our adversaries.
Generally, a magnetic coil is a continuous electrically insulated wire or other suitable conductive material that is looped partially and, or completely a number of times around an axis. A magnetic field is caused when electrical current passes through such a coil in accordance with the applicable physics. Applicable physics also describes how a magnetic coil converts electrical energy to magnetic energy which energy is stored in the magnetic field of the coil and dissipated by magnetically-induced eddy currents in conductive materials.
Magnetic fields permeate the medium surrounding the source magnetic dipole and an attractive or repulsive force may result depending upon whether there is a net reduction or increase in energy because of it. A magnetic coil with an applied DC current may create a similar magnetic field with the same repulsive and attractive effects. However, the magnetic coil also features an electrical impedance; and this impedance is influenced by the media the magnetic field passes through. Therefore, according to an embodiment, it is possible to sense a remote object possessing magnetic and conductive properties by understanding and exploiting how the object influences the impedance of a magnetic coil and the circuit that includes the coil.
The behavior of a transformer, under the influence of an alternating current, is instructive to understanding the basic concepts of magnetic sensing through the agency of a magnetic coil. A transformer is two electrically distinct coils arranged to optimize the transfer of alternating current (AC) electrical power (with minimal loss) between the coils. Since energy is conserved in the ideal transformer, the power into the primary coil of such a transformer is equal to the power output by the secondary coil of the transformer. Typically, the impedance of electrical components connected to complete a circuit including the secondary coil of the transformer affect the impedance of the primary coil of the transformer. Thus, the resistive, capacitive and inductive properties of components contained in a circuit including the secondary coil of the transformer may be determined by measuring the impedance of the primary coil and performing an appropriate analysis.
An alternating magnetic field, caused by a sinusoidal current passing through a magnetic coil, causes several effects in materials permeated by the magnetic field. Sinusoidal magnetic fields induce eddy currents in conductive materials permeated by the magnetic field. Magnetic fields alter the magnetic polarization of ferromagnetic materials and induce magnetic polarization in magnetically susceptible materials. If the magnetic field is sinusoidal, these effects will sympathetically follow the sinusoidal influence of the causal magnetic field at low frequencies up to a frequency (unique to each effect) above which each effect begins to diminish due to a finite response.
Remote eddy currents induced by the AC magnetic field of the coil increase the resistance of the coil. Remote magnetic polarization of material by the influence of the AC magnetic field of the coil affects the inductance of the coil. The diamagnetic or paramagnetic qualities of the medium, and objects permeated by the magnetic field, cause a decrease or increase in the inductance of the coil. These resistive and inductive effects in the coil are sensible by the way the coil affects a circuit to which it is connected as a functional component.
According to an embodiment an optimal sensing coil circuit is provided to enable distinct outputs inferential of the magnetic and resistive properties of media and objects permeated by the magnetic field of the coil. Generally, any circuit containing a coil may be used to implement the present invention. Extensive study and testing of various circuits suggests that a bridge circuit containing a coil provides optimal performance. The Owens bridge, the Hay bridge and the Maxwell-Wien bridge are typical impedance bridges and all three are suitable for inductance sensing.
A useful bridge circuit for magnetic sensing with a coil takes advantage of such phase and voltage relationships illustrated in
As shown in
As shown in
According to an embodiment of the sensor, capacitors are carefully chosen to be precisely matched in each of the various arms of the sensor (
When the Owens Bridge is nulled, the triangles in
The AC resistance of the coil is altered from its quiescent value, RX, to a perturbed value, RX+rX, at frequencies below the response frequency of the inducible eddy currents, by power loss to said eddy currents induced in conductive materials permeated by the AC field of the coil. The imbalance (Shown in the right side of
The AC inductance of the coil is altered from its quiescent value, LX, to a perturbed value, LX±lX, at frequencies below the response frequency of the magnetically susceptible materials, by increased or decreased energy storage in the magnetic polarization of susceptible materials permeated by the AC field of the coil. In diamagnetic materials the material polarization opposes the field with a net reduction in energy storage and an attendant reduction in the inductance of the coil. In paramagnetic materials the material polarization enhances the field with a net increase in energy storage and an attendant increase in the inductance of the coil. The imbalance (Shown in the left side of
A new method and means for rapidly and adaptively nulling the bridge shown in
This optical nulling technique is easily automated with a simple bisection algorithm. The optical control is determined during a test sensing procedure to automatically null the bridge for the ambient static or temporal clutter in the absence of a sought object. An example of temporal clutter is the periodic clutter presented by placing the sensor on a moving (rolling variable wheels) vehicle. An example of static clutter is that presented by the ground occulting a buried landmine.
Generally, the signals produced by the magnetic effects sensor are complex and information rich. This complexity affords the opportunity to use several filtering methods to process the signals for their information. From Linear Algebra it is known that the number of sought objects discriminated, N, requires the same number of distinct parameters. These parameters are the in-phase and quadrature amplitudes of the bridge response signal at each distinguishable signal frequency applied to the bridge.
Matched filtering and novelty filtering are two methods that offer superior performance for myriad magnetic effect sensing applications. A filter is the sum of products of the weighted mean-removed signal, Si, and target template, Ti, generally represented mathematically as
The numerical weight, Wi, increases proportional to the significance attributed to the products. For Optimal Matched Filtering the weight scales inversely with signal noise and clutter. Matched Filtering produces an output that is proportional to the degree of similarity of the signals to a template. Each sought target template is a distinct channel output for this filter. The following plot shows the matched (red) and unmatched (blue) filter output.
For Novelty Filtering, the calibrated mean-removed clutter signal is the template, the mean-removed sensed clutter is the signal and the deviation of the product output from one is proportional to the novelty from calibrated clutter. Statistically significant deviations from the calibrated clutter may indicate interesting signals telling of novelty.
Simple comparisons provide a fast (though sub-optimal) Matched Filter algorithm that lends itself to phase and quadrature amplitude comparison at AC frequencies.
As shown in
According to an embodiment, the sensor capitalizes on many of the sensing nuances and engineering possibilities. For example, the system of the present invention detects phase behavior such as an AC voltage drop occurs across a component as a consequence of the AC current flowing through that component including, the sine wave phase of the AC voltage drop across a resistor shares phase with the sine wave AC current flowing through that resistor, the The sine wave phase of the AC voltage drop across a capacitor depends on the accumulation of charge on the electrodes and lags behind, by ninety degrees, the sine wave AC phase of the current flowing through that capacitor, and the sine wave phase of the AC voltage drop across a coil depends on the magnetic field produced by the coil and leads, by ninety degrees, the sine wave AC phase of the current flowing through that coil.
The nulling (balancing) the bridge circuit is implemented where the current flowing in each arm of the bridge is the same current at the same phase through each series component in each arm. This means that the voltage drops across each of the components is produced to cause a voltage drop between two measurement points, one point each in each arm. This voltage drop is called the Bridge Signal.
The Bridge Signal may be nulled (meaning it has a zero AC voltage drop when the bridge is nulled) and may have an AC voltage amplitude at some phase relative to that of the AC Bridge Excitation Signal when the bridge is imbalanced. Nulling the bridge is easier at the resonant frequency of the capacitor and coil in the measurement arm of the bridge. Nulling the bridge becomes practical and straight-forward if the capacitors have the same capacitance. This is because the AC voltage drops at that frequency across each component in any arm are all equal in voltage at null.
The bridge resistors can be replaced by a photoconductive photocell under optical control to provide an adjustable Precision Variable Resistor (PVR) that can be under automatic control. The benefit of a Precision Variable Resistor is they stabilize the bridge against resistive drifts away from null.
According to an embodiment, an automated adjustment of the PVRs is provided to null the bridge with the highest precision without measuring AC voltage drops across the bridge components. This is done by using the fact that, when the phase of the Reference Signal is set to be 45 degrees relative to that of the Bridge Excitation Signal at the L-C resonance frequency, the changes in the Bridge Signal caused by changing the resistance of the two PVRs are independent of each other and are perfectly aligned with the In-phase and Quadrature components produced by Coherent Processing. Under this set of amazing relationships, the bridge is nulled by simply setting the In-phase signal to zero by adjusting one PVR and adjusting the Quadrature signal to zero by adjusting the other PVR. This allows us to avoid conducting AC voltage drop measurements, which would draw current and negatively impact our nulling precision.
Dealing with Parasitics. An Owen Bridge, constructed of ideal components, remains nulled at all bridge AC excitation frequencies. A frequency-dependent correction may be applied to the output signal of the nulled bridge because of the parasitic impedances of imperfect bridge components. In an embodiment, the necessary offset correction may be minimized by engineering improved bridge components with minimal parasitics.
Signal response association to threat objects. The inductance of the coil will vary from its value used to null the bridge proportionate to the paramagnetic and diamagnetic properties of objects placed in the AC field of the coil. These properties imbalance the bridge. In an embodiment, paramagnetic and diamagnetic influences may be associated to a particular threat object.
The resistance of a component is equal to the ratio of power dissipated by that component and the current flowing through it. An electrical coil has an AC resistance that can be different from the DC resistance that may be measured with a voltmeter. The MES exploits the AC coil resistance caused by a power loss from the AC magnetic field of the coil to objects in that field that absorb and dissipate that power. This imbalances the bridge, and may provide valuable clues to a threat object.
The imbalance signal of the bridge for a change in the coil inductance is electrically-distinguishable from the imbalance signal for a change in the coil resistance. This capability may be exploited to help us identify a threat object.
Advanced Signal Processing. The fact that the AC Bridge Signal has the same frequency as the AC Bridge Excitation Signal means that Coherent Processing, with a Reference Signal that is derived from the Bridge Excitation Signal, may be used to process the Bridge Signals to achieve the very high sensitivity that is possible with other techniques such as laser interferometry. The Coherent Processing can distinguish phase differences between the Bridge Signal and the Reference Signal into two AC components that sum to the Bridge Signal. These components as the In-phase and Quadrature components.
The In-phase component has the same AC phase as the Reference Signal. The Quadrature component has an AC phase that is shifted ninety degrees in phase away from the AC phase of the Reference Signal. Sensing performance over a range of AC frequencies. At the L-C resonance frequency, the nulling point in the Nulling Arm is midway between the maximum and minimum AC Excitation Voltage. The nulling point moves to minimize the linear bridge imbalance signal range for a change in coil impedance and the effects of parasitic impedances become increasingly pronounced with increasing or decreasing frequency away from the L-C resonance frequency where the best null was achieved. Good sensing performance can be expected with the MES over a range of frequencies from a half resonant frequency to twice resonant frequency of the sensor.
According to an embodiment, a magnetic effects sensor can be deployed as either a hand-held or vehicle mounted sensor for detecting buried/hidden objects of interest. It can also be applied to many other sensing requirements in private industry. It can be engineered into an extremely small form factor, with flea-power energy requirements. Unlike an induction sensor or other similar sensors, the disclosed sensor can detect objects including those that have absolutely no metal components. Unlike an induction sensor, the MES does not send out an active signal.
The idea behind the MES is to produce a very sensitive device that measures changes to the resistance and inductance of the sensing coil, across an AC frequency range. These changes to the sensing coil are responses induced by the interaction of the coil with an area of interest. Across the AC frequency range, at each step frequency, the MES detects both the resistance and the inductance changes—independently of each other. The MES components are selected with a particular frequency range in mind—selected based upon some knowledge of the targets of interest. This information can be exploited for target discrimination.
The embodiments can be implemented in computing hardware (computing apparatus) and/or software, such as (in a non-limiting example) any computer that can store, retrieve, process and/or output data and/or communicate with other computers. The results produced can be displayed on a display of the computing hardware. A program/software implementing the embodiments may be recorded on computer-readable media comprising computer-readable recording media. The program/software implementing the embodiments may also be transmitted over transmission communication media. Examples of the computer-readable recording media include a magnetic recording apparatus, an optical disk, a magneto-optical disk, and/or a semiconductor memory (for example, RAM, ROM, etc.). Examples of the magnetic recording apparatus include a hard disk device (HDD), a flexible disk (FD), and a magnetic tape (MT). Examples of the optical disk include a DVD (Digital Versatile Disc), a DVD-RAM, a CD-ROM (Compact Disc-Read Only Memory), and a CD-R (Recordable)/RW. An example of communication media includes a carrier-wave signal.
Further, according to an aspect of the embodiments, any combinations of the described features, functions and/or operations can be provided.
The many features and advantages of the embodiments are apparent from the detailed specification and, thus, it is intended by the appended claims to cover all such features and advantages of the embodiments that fall within the true spirit and scope thereof. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the inventive embodiments to the exact construction and operation illustrated and described, and accordingly all suitable modifications and equivalents may be resorted to, falling within the scope thereof.
This application is related to and claims priority to U.S. Provisional Application Ser. No. 61/368,125, entitled MAGNETIC EFFECTS SENSOR, inventors Joseph T. Siewick, et al., filed Jul. 27, 2010, in the United States Patent and Trademark Office, the disclosure of which are incorporated herein by reference.
Number | Date | Country | |
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61368125 | Jul 2010 | US |