Apparatus for Sensor with Configurable Coil and Associated Methods

TECHNICAL FIELD

The disclosure relates generally to sensors, such as acceleration, speed, and displacement sensors and, more particularly, to apparatus for such sensors with configurable coils, and associated methods.

BACKGROUND

With advances in electronics, a variety of sensors have been developed to sense physical quantities. The sensors may use a variety of technologies, such as electrical, mechanical, optical, and micro-electromechanical systems (MEMS), or combinations of such technologies. More particularly, some sensors can sense displacement, velocity, or acceleration. Sensors that can sense displacement, velocity, or acceleration find use in a variety of fields, such as ground or earth exploration, for instance, reflection seismology.

As an example, devices known as geophones use a magnet and a coil that move relative to each other in response to ground movement. Waves sent into the earth generate reflected energy waves. In response to reflected energy waves, geophones generate electrical signals that may be used to locate underground objects, such as natural resources.

FIG. 1 illustrates a conceptual diagram 10 of a geophone, which includes a magnet 16 coupled to an anchor point 12 (e.g., housing) and spring 14, and coil 18 with mass m. In response to a stimulus, such as the energy waves described above, coil 18 moves in relation to magnet 16. As a result, an electrical output signal is generated by coil 18.

The coil-spring assembly form a physical system that responds non-uniformly as the frequency of the stimulus is varied. Assuming that spring 14 has a spring constant k, the coil-spring assembly, with mass m (i.e., a negligible spring mass), has a natural frequency of oscillation of

$f_{N} = \sqrt{\frac{k}{m}} .$

FIG. 2 illustrates a frequency response curve 20 of the geophone of FIG. 1 to physical stimuli. Frequency response curve 20 has a peak 23 at the frequency f_N. Thus, geophone 10 has better response (higher output signal level) at frequencies near or equal to f_N.

Note that the description in this section and the corresponding figures are included as background information material. The materials in this section should not be considered as an admission that such materials constitute prior art to the present patent application.

SUMMARY

According to an exemplary embodiment, an apparatus includes a network of switchable coils suspended in a magnetic field, wherein a topology of the network of switchable coils may be configured to change at least one characteristic of a sensor, and an optical detector to detect displacement of the coil in response to a stimulus. The apparatus further includes a feedback circuit coupled to the optical detector and to the network of switchable coils.

According to another exemplary embodiment, a system includes a sensor. The sensor includes a plurality of switchable coils suspended in a magnetic field, and an optical detector to detect displacement of the plurality of switchable coils in response to a stimulus, and a feedback circuit coupled to the optical detector and to the coil. The sensor further includes a controller coupled to the plurality of switchable coils to couple the plurality of coils in a series configuration or in a parallel configuration.

According to another exemplary embodiment, a method of operating a sensor is disclosed. The sensor includes a network of switchable coils suspended in a magnetic field, an optical detector to detect displacement of the coil in response to a stimulus, and a feedback circuit coupled to the detector and to the network of switchable coils. The method includes configuring a topology of the network of switchable coils to change at least one characteristic of the sensor.

BRIEF DESCRIPTION OF THE DRAWINGS

The appended drawings illustrate only exemplary embodiments and therefore should not be considered as limiting the scope of the application or the claims. Persons of ordinary skill in the art appreciate that the disclosed concepts lend themselves to other equally effective embodiments. In the drawings, the same numeral designators used in more than one drawing denote the same, similar, or equivalent functionality, components, or blocks.

FIG. 1 illustrates a conceptual diagram of a geophone.

FIG. 2 depicts the frequency response of a geophone in response to physical stimuli.

FIG. 3 shows a sensor according to an exemplary embodiment.

FIG. 4 depicts forces operating in a sensor according to an exemplary embodiment.

FIG. 5 illustrates a virtual spring caused by use of negative feedback in an exemplary embodiment.

FIG. 6 depicts a cross-section of a sensor according to an exemplary embodiment.

FIG. 7 illustrates a cross-section of a sensor according to an exemplary embodiment.

FIG. 8 shows a schematic diagram of a sensor according to an exemplary embodiment.

FIG. 9 illustrates a schematic diagram of a sensor according to an exemplary embodiment.

FIG. 10 depicts an output signal of a trans-impedance amplifier (TIA) in an exemplary embodiment.

FIG. 11 shows a flow diagram for a method of operating a sensor according to an exemplary embodiment.

FIG. 12 illustrates a block diagram of a sensor communicating with another device or component according to an exemplary embodiment.

FIG. 13 depicts a circuit arrangement for a sensor with a plurality of coils coupled in a series configuration according to an exemplary embodiment.

FIG. 14 illustrates a circuit arrangement for the embodiment of FIG. 13 with the plurality of coils coupled in a parallel configuration.

FIG. 15 shows a circuit arrangement for a sensor with a network of switchable coils according to an exemplary embodiment.

FIG. 16 depicts a network of switchable coils according to an exemplary embodiment.

FIG. 17 illustrates a network of switchable coils according to another exemplary embodiment.

FIG. 18 shows a network of switchable coils according to another exemplary embodiment.

FIG. 19 depicts a network of switchable coils according to yet another exemplary embodiment.

FIG. 20 illustrates a network of switchable coils according to yet another exemplary embodiment.

DETAILED DESCRIPTION

The disclosed concepts relate generally to sensors, such as acceleration, speed, and displacement sensors. More specifically, the disclosed concepts provide systems, apparatus, and methods for sensors with configurable coils, such as coils that may be configured in series or in parallel, etc.

Sensors according to exemplary embodiments can sense acceleration, velocity, and/or displacement. As persons of ordinary skill in the art understand, acceleration, velocity, and displacement are governed by mathematical relationships. Thus, one may sense one of acceleration, velocity, and displacement, and derive the others from it.

For example, if acceleration, a, is sensed, velocity, v, and displacement, x, may be derived from a. More specifically:

$a = \frac{\partial v}{\partial t} \Rightarrow v = \int a \cdot \partial t$

$v = \frac{\partial x}{\partial t} \Rightarrow x = \int v \cdot \partial t$

Sensors according to exemplary embodiments include a combination of electrical, optical, and mechanical components. FIG. 3 illustrates a conceptual diagram of a sensor 100 according to an exemplary embodiment.

Referring to FIG. 3, sensor 100 includes a spring 106 attached (e.g., at one end) to an acceleration reference frame or plane 103. Spring 106 has a spring constant k_s. Spring 106 is also attached (e.g., at another end) to coil 109. Coil 109 and its corresponding assembly (not shown), e.g., a bobbin, have a mass m, also known as proof mass.

A magnet 112 is positioned near or proximately to coil 109. A magnetic field 112A is established between the north and south poles of magnet 112. Thus, coil 109 is completely or partially suspended within magnetic field 112A. By virtue of spring 106, coil 109 may move in relation to magnet 112 and, thus, in relation to magnetic field 112A.

More specifically, in response to a physical stimuli, such as a force that causes displacement x of coil 109, coil 109 moves in relation to magnet 112 and magnetic field 112A. As persons of ordinary skill in the art understand, movement of a conductor, such as coil 109, in a magnetic field, such as magnetic field 112A, induces a current in the coil. Thus, in response to the stimuli, coil 109 produces a current.

Optical position sensor 115 detects the movement of coil 109 in response to the stimuli. More specifically, as described below in detail, optical position sensor 115 generates an output signal, for example, a current, in response to the movement of coil 109.

Note that in some embodiments, rather than generating a current, optical position sensor 115 may generate a voltage signal. For example, optical position sensor 115 may include a mechanism, such as an amplifier or converter, to convert a current produced by the electro-optical components of optical position sensor 115 to an output voltage. In either case, optical position sensor 115 provides an output signal 115-1 to amplifier 118.

Without loss of generality, in exemplary embodiments, amplifier 118 constitutes a TIA. TIA 118 generates an output voltage in response to an input current. Thus, in the case where optical position sensor 115 provides an output current (rather than an output voltage) 115-1, TIA 118 converts the current to a voltage signal.

In some embodiments, depending on a number of factors, TIA 118 may include circuitry for driving coil 109, such as a coil driver (not shown). Such factors include design and performance specifications for a given implementation, for example, the amount of drive specified for coil 109, etc., as persons of ordinary skill in the art will understand.

TIA 118 (or other amplifier circuitry, as noted above) provides an output signal 118-1 to coil 109. The polarity of output signal 118-1 is selected such that output signal 118-1 counteracts the current induced in coil 109 in response to the physical stimuli. In other words, optical position sensor 115 and TIA 118 couple to coil 109 so as to form a negative-feedback loop.

The feedback or driving signal, i.e., signal 118-1, causes a force to act on coil 109. In exemplary embodiments, the force is proportional to the displacement x. Thus, a force exerted by spring 106 and a force exerted by coil 109 (by virtue of negative feedback and driving signal 118-1) cooperate with each other against the force created by acceleration of coil 109 (the proof mass). FIG. 4 illustrates the two forces.

More specifically, FIG. 4 shows a force vector 121 that corresponds to force F_sexerted by spring 106. FIG. 4 also depicts a force vector 124 that corresponds to force F_cexerted by virtue of the acceleration of coil 109. According to Hook's law, force F_srelates to displacement x, specifically F_s=−k_s·x, where, as noted above, k_srepresents the spring constant of spring 106. In effect, spring 106 resists the displacement in proportion to k_s.

Furthermore, according to Newton's second law (ignoring any relativistic effects), force F_crelates to the mass of coil 109 (including any physical components, such as a bobbin), and to the acceleration that coil 109 experiences as a result of the external stimuli (e.g., the source that causes displacement x to occur). Specifically, F_c=m_c·a, where m_crepresents the mass of coil 109, and a denotes the acceleration that coil 109 experiences.

As noted above, negative feedback is employed in sensor 100 (see FIG. 5) so as to cause the mass m_cto come to equilibrium. Mathematically stated, the feedback causes the mass m_cto come to equilibrium when F_sequals F_c. Thus, sensor 100 may be viewed as operating according to a force-balance principle, i.e., F_s=F_cat equilibrium.

Stated another way, force-balance occurs when −k_s·x=m_c·a. One may readily determine the spring constant k_sand the mass of coil 109, m_c(e.g., by consulting data sheets or controlling manufacturing processes, etc.). Using the values of k_sand m_cin the above equation, one may determine the acceleration of coil 109 in response to the stimulus, i.e.:

$a = \frac{- k_{s} \cdot x}{m_{c}} .$

In other words, output signal 118-1 of TIA 118 is proportional to acceleration a. Given acceleration a, velocity v, and displacement x may be determined, by using the mathematical relations described above. (Note also that optical position sensor 115 may also determine displacement x). Thus, sensor 100 may be used to determine displacement (position), velocity, and/or acceleration, as desired.

Using negative feedback provides a number of benefits. First, it flattens or tends to flatten the response of sensor 100 to the stimuli. Second, feedback increases the frequency response of sensor 100, i.e., sensor 100 has more of a broadband response because of the use of feedback.

Third, negative feedback reduces the amount of displacement that results in a desired output signal level. In effect, negative feedback acts as a virtual spring coupled in parallel with spring 106, a concept that FIG. 5 illustrates. More specifically, the negative-feedback signal applied to coil 109 causes virtual spring 130 to counteract force F_c, which is exerted because of the acceleration of coil 109, as described above. Thus, spring 106 and virtual spring 130 work as additive forces to reach force equilibrium in opposition to the force created by acceleration of the coil mass (proof mass). Virtual spring 130 is controlled electronically, e.g., by TIA 118 in FIG. 3.

Referring again to FIG. 5, because of the use of negative feedback, virtual spring 130 has a larger spring constant, k_v, than does spring 106. Use of virtual spring 130 results in sensor 100 creating a given output in response to a smaller stimulus. Put another way, virtual spring 130 acts as a stiff spring. Thus, compared to an open-loop arrangement, sensor 100 has a reduced total displacement for a desired level of output signal. Also, force applied to a sensor that uses an open-loop arrangement (e.g., a geophone), causes the mass suspended by the spring to wobble more, which limits the upper response limit of the sensor.

As noted, use of negative feedback flattens or tends to flatten the sensor frequency response, and also reduces the sensitivity of the force-balance system to the value of spring constant k_sof spring 106, since the spring constant of virtual spring 130 dominates. A benefit of the foregoing is to allow the use of a stiffer spring suspension 106, which in turn facilitates sensor operation at any orientation with respect to Earth's gravity. Additionally, an increase in loop gain results in a stiffer virtual spring constant 130, which in turn allows a larger full scale stimulus range.

Note that a variety of embodiments of sensors according to the disclosure are contemplated. For example, in some embodiments, the position of coil 109 and magnet 112 may be reversed or switched (see FIG. 3). Thus, coil 109 may be stationary, while magnet 112 may be suspended by spring 106.

As another example, in some embodiments, more than one magnet 112 may be used, as desired. As yet another example, in some embodiments, more than one coil 109 may be used, e.g., two coils in parallel or series, as desired. Other arrangements are possible, depending on factors such as design and performance specifications, cost, available technology, etc., as persons of ordinary skill in the art will understand.

FIG. 6 depicts a cross-section of a sensor 200 according to an exemplary embodiment. Sensor 200 includes a housing, frame, or enclosure 205 to provide physical support for various components of sensor 200. In the embodiment shown, housing 205 has sides 205A, 205B, 205C, and 205D, for example, a top, a right side or wall, a bottom, and a left side or wall. Other housing, frames, or enclosures are possible and contemplated, as persons of ordinary skill in the art will understand.

Magnet 112 is arranged with magnet caps 215A and 215B. In the embodiment shown, magnet 112 is disposed between magnet caps 215A and 215B. A variety of types and shapes of magnets may be used, as desired. Examples include neodymium-iron-boron (NIB) or aluminum nickel cobalt (ALNICO) alloy magnets, but other materials, such as alloys with appropriate properties, may be used. Other arrangements of the magnet and magnet caps or support are possible and contemplated, as persons of ordinary skill in the art will understand.

Coil 109 is wound on a bobbin 220. In the embodiment shown, coil 109 and bobbin 220 together form the proof mass (neglecting the mass of spring 106). In the embodiment shown, coil 109 is wound in two sections on bobbin 220, although other arrangements are possible and contemplated, as persons of ordinary skill in the art will understand.

The proof mass is suspended by spring 106, which for illustration purposes is shown as four sections labeled 106A-106D. In exemplary embodiments, spring 106 may include one, two, or more springs, such as flat, leaf, or spider springs, as desired. Other types and/or arrangements of spring 106 are possible and contemplated, as persons of ordinary skill in the art will understand. A variety of materials and techniques may be used to fabricate spring 106. Some examples include etching or die cutting. Beryllium copper may be used as one example of spring material, but other materials with appropriate spring properties (e.g., having relatively low temperature coefficient) may be used, as desired.

In exemplary embodiments, such as the embodiment of FIG. 6, spring 106 may have a relatively low spring constant. More specifically, spring 106 may have sufficient stiffness to suspend and support the proof mass. As noted above, a virtual spring (not shown) having a relatively high spring constant (i.e., higher than the spring constant of spring 106) operates in conjunction with spring 106. Thus, spring 106 may provide just enough stiffness to physically support the proof mass.

In the embodiment shown in FIG. 6, spring 106 (shown as sections or portions 106A-106D) suspend the proof mass with respect to magnet 112 (and magnet caps 215A-215B, if used). In other words, a stimulus, such as force, applied to sensor 200 causes the proof mass to move or experience a displacement with respect to magnet 112 (and magnet caps 215A-215B). Other arrangements are possible and contemplated, as persons of ordinary skill in the art will understand. For example, spring 106 may attach to housing 205, rather than magnet caps 215A-215B.

Sensor 200 includes an optical interferometer to generate an electrical signal in response to displacement of coil 109 in relation to magnet 112 or housing 205. The electrical signal constitutes the output of the optical interferometer. The electrical signal may be provided to an amplifier, e.g., TIA 118 in FIG. 3.

Referring again to FIG. 6, in the embodiment shown, the optical interferometer includes a light source 225, such as a vertical cavity surface-emitting laser (VCSEL). The light output of light source 225 is reflected by a mirror 222, and is diffracted by diffraction grating 235. The resulting optical signals are detected by optical detectors 230A, 230B, and 230C.

A mechanical or physical stimulus applied to sensor 200 causes a change in the detected light, and thus causes optical detectors 230A-230C to provide an electrical output signal. The electrical output signal, e.g., a current signal, may be used in a feedback loop, as discussed above.

Note that, if desired, the electrical output signal may be used in an open-loop configuration, rather than in a closed-loop (negative feedback) configuration. As noted above, closed-loop configuration provides some advantages over open-loop configuration. In some situations, however, operating sensor 200 in an open-loop configuration may be desired, for instance, on a temporary basis.

FIG. 7 depicts a cross-section of a sensor 250 according to an exemplary embodiment. Sensor 250 includes a housing, frame, or enclosure 205 to provide physical support for various components of sensor 250. In the embodiment shown, housing 205 has sides 205A, 205B and 205C, for example, a right side or wall, a bottom, and a left side or wall. Other housing, frames, or enclosures are possible and contemplated, as persons of ordinary skill in the art will understand.

Magnet 112 is arranged with magnet caps 215A, 215B, and 215C. In the embodiment shown, magnet 112 is attached to magnet cap 215B, which is disposed against or in contact with magnet caps 215A and 215C. A variety of types and shapes of magnets may be used, as desired. As noted, examples include neodymium-iron-boron (NIB) or aluminum nickel cobalt (ALNICO) alloy magnets, but other materials, such as alloys, with appropriate properties can be used. In some embodiments, magnet 112 may extend to a cavity in bobbin 220 (described below). Other arrangements of the magnet and magnet caps or support are possible and contemplated, as persons of ordinary skill in the art will understand.

Coil 109 is wound on a bobbin 220. In the embodiment shown, coil 109 and bobbin 220 together form the proof mass (neglecting the mass of spring 106). In the embodiment shown, coil 109 is wound around bobbin 220, although other arrangements are possible and contemplated, as persons of ordinary skill in the art will understand.

The proof mass is suspended by spring 106, which for illustration purposes is shown as four sections labeled 106A-106D. In exemplary embodiments, spring 106 may include one, two, or more springs, such as flat, leaf, or spider springs, as desired. Other types and/or arrangements of spring 106 are possible and contemplated, as persons of ordinary skill in the art will understand. As noted above, a variety of materials and techniques may be used to fabricate spring 106. Some examples include etching or die cutting. Beryllium copper may be used as one example of spring material, but other materials with appropriate spring properties (e.g., having relatively low temperature coefficient) may be used, as desired.

In exemplary embodiments, such as the embodiment of FIG. 7, spring 106 may have a relatively low spring constant. More specifically, spring 106 may have sufficient stiffness to suspend and support the proof mass. As noted above, a virtual spring (not shown), having a relatively high spring constant (i.e., higher than the spring constant of spring 106) operates in conjunction with spring 106. Thus, spring 106 may provide just enough stiffness to physically support the proof mass.

In the embodiment shown in FIG. 7, spring 106 (shown as sections or portions 106A-106D) suspend the proof mass with respect to magnet 112 (and magnet caps 215A-215C, if used). In other words, a stimulus, such as force, applied to sensor 250 causes the proof mass to move or experience a displacement with respect to magnet 112 (and magnet caps 215A-215C). Other arrangements are possible and contemplated, as persons of ordinary skill in the art will understand. For example, spring 106 may attach to magnet caps 215A and 215C, rather than housing 205.

Sensor 250 includes an optical interferometer to generate an electrical signal in response to displacement of coil 109 in relation to magnet 112 or housing 205. The electrical signal constitutes the output of the optical interferometer. The electrical signal may be provided to an amplifier, e.g., TIA 118 in FIG. 3.

Referring again to FIG. 7, in the embodiment shown, the optical interferometer includes a light source 225, such as a VCSEL. The light output of light source 225 is reflected by a mirror 222, and is diffracted by diffraction grating 235. The resulting optical signals are detected by optical detectors 230A, 230B, and 230C.

A stimulus applied to sensor 250 causes a change in the detected light, and thus causes optical detectors 230A-230C to provide an electrical output signal. The electrical output signal, e.g., a current signal, may be used in a feedback loop, as discussed above.

Note that, if desired, the electrical output signal may be used in an open-loop configuration, rather than in a closed-loop (negative feedback) configuration. As noted above, closed-loop configuration provides some advantages over open-loop configuration. In some situations, however, operating sensor 250 in an open-loop configuration may be desired, for instance, on a temporary basis.

FIG. 8 shows a schematic diagram or circuit arrangement 300A for a sensor according to an exemplary embodiment, for instance sensors 200 and 250 in FIGS. 6 and 7, respectively. Referring to FIG. 8, as described above, optical detectors 230A-230C (photodiodes in the embodiment shown) provide an output signal to TIA 118. A bias source, labeled V_BIAS, for example, ground or zero potential, provides an appropriate bias signal to detectors 230A-230C. In the embodiment of FIG. 8, the output signal of optical detectors 230A-230C is provided to TIA 118 as a differential signal.

Note that FIG. 8 omits light source 225 for the sake of clarity of presentation. Light source 225, e.g., a VCSEL, may be powered by an appropriate circuit (not shown). Examples include a voltage regulator, a reference source, etc., as desired. Also, in some embodiments, MCU 310 may control or program the light level that light source 225 emits, depending on various factors, such as power consumption, desired sensor parameters and performance, etc.

In the embodiment shown in FIG. 8, TIA 118 includes two individual TIA circuits or amplifiers, 118A and 118B, to accommodate the differential input signal. TIA 118 includes resistors 305A-305B to adjust (or calibrate or set or program or configure) the gain of TIAs 118A-118B, respectively.

Thus, by adjusting resistor 305A, the gain of amplifier 118A may be adjusted. Similarly, by adjusting resistor 305B, the gain of amplifier 118B may be adjusted. A controller, such as a microcontroller unit (MCU) 310 in the exemplary embodiment shown, adjusts the values of resistors 305A-305B.

Typically, given the differential nature of the input signal of TIA 118, MCU 310 adjusts resistors 305A-305B to the same resistance value so as to increase or improve the common-mode rejection ration (CMRR) of TIA 118. Put another way, the two branches of TIA 118, i.e., the branches containing amplifiers 118A and 118B, respectively, are typically matched by adjusting resistors 305A-305B to the same resistance value. In some situations, however, resistors 305A-305B might be adjusted to different values, for example to compensate for component mismatch, manufacturing variations, etc.

Note that adjusting the gains of amplifiers 118A-118B does not set the full-scale range of the sensor. Rather, the gains of amplifiers 118A-118B determine the overload point of the sensor, i.e., the peak overload point of the sensor in response to a stimulus. Furthermore, the coil constant of coil 109 determines the magnitude of the output signal of the sensor in response to a given amount of acceleration in response to a stimulus, such as force. The coil constant is defined in units of Newtons per Ampere. Increasing the coil constant increases the full-scale range of the sensor for a given available or applied coil current. For fixed values of resistors 320A and 320B, the effect of increasing coil constant is a decrease in the sensor's scale factor in terms of Volts per unit of stimulus (e.g., acceleration (g)), as force-balance equilibrium will be reached at a lower coil current (and hence output voltage) for a given stimulus value.

The output of amplifier 118A feeds one end or terminal of coil 109 via resistors 315A and 320A. Conversely, the output of amplifier 118B feeds the other end of coil 109 via resistors 315B and 320B. Thus, amplifiers 118A-118B provide a drive signal for coil 109 via resistors 315A-315B and 320A-320B.

MCU 310 may adjust (or calibrate or set or program or configure) the values of resistors 320A-320B. Similar to resistors 305A-305B, typically, given the differential nature of the output signal of the sensor, MCU 310 adjusts resistors 320A-320B to the same resistance value. In some situations, however, resistors 320A-320B might be adjusted to different values, for example to compensate for component mismatch, manufacturing variations, etc.

Note that the values of resistors 320A-320B affect the gain or scale factor of the sensor. In other words, the values of resistors 320A-320B determine the full range or scale that the sensor can sense, e.g., the full range of acceleration in response to the stimulus.

Nodes 325A and 325B provide the differential output signal of the sensor. In the embodiment shown, node 325A provides the positive output signal, whereas node 325B provides the negative output signal. Together, the positive and negative output signals provide a differential output signal that is proportional to acceleration, a, experienced by the proof mass in response to the stimulus (e.g., force), as discussed above.

In some embodiments, MCU 310 may include circuitry to receive and process the output signal provided at nodes 325A-325B. For example, MCU 310 may include analog-to-digital converter (ADC) circuitry to convert the output signal at nodes 325A-325B to a digital quantity. MCU 310 may communicate the resulting digital quantity to another circuit or component, for example, via link 370, as desired. Furthermore, MCU 310 may receive power (to supply the various components in the sensor) or other information, for example, parameters related to adjusting various resistor values, as described above, via link 370.

FIG. 9 shows a schematic diagram or circuit arrangement 300B for a sensor according to an exemplary embodiment, for instance sensors 200 and 250 in FIGS. 6 and 7, respectively. Referring to FIG. 9, as described above, optical detectors 230A-230C (photodiodes in the embodiment shown) provide an output signal to TIA 118. In the example shown, V_BIASis ground potential although, as noted above, other appropriate values may be used. In the embodiment of FIG. 9, the output signal of optical detectors 230A-230C is provided to TIA 118 as a single-ended signal.

Note that FIG. 9 omits light source 225 for the sake of clarity of presentation. Light source 225, e.g., a VCSEL, may be powered by an appropriate circuit (not shown). Examples include a voltage regulator, a reference source, etc., as desired. Also, in some embodiments, MCU 310 may control or program the light level that light source 225 emits, depending on various factors, such as power consumption, desired sensor parameters and performance, etc.

The gain of TIA 118 may be adjusted by adjusting (or calibrating or setting or programming or configuring) resistor 305. In the embodiment shown, MCU 310 adjusts the values of resistor 305. In other embodiments, other arrangements may be used, as desired, for example, use of a host or controller coupled to the sensor, described below.

The output of TIA 118 drives an input of amplifier 345 via resistor 335. A feedback resistor 340 couples the output of amplifier 345 to resistor 335 (input of amplifier 345). If desired, the gain of amplifier 345 may be adjusted by adjusting resistor 340 (more specifically, the ratio of resistors 340 and 335). In the embodiment shown, MCU 310 may adjust the value of resistor 345.

The output of amplifier 345 drives an input of amplifier 355 via resistor 350. A feedback resistor 360 couples the output of amplifier 355 to resistor 350 (input of amplifier 355). If desired, the gain of amplifier 355 may be adjusted by adjusting resistor 360 (more specifically, the ratio of resistors 360 and 350). In the embodiment shown, MCU 310 may adjust the value of resistor 360.

Note that adjusting the gain of TIA 118 (and optionally the gains of amplifiers 345 and 355) does not set the full-scale range of the sensor. Rather, the gain of TIA 118 (and optionally the gains of amplifiers 345 and 355) determines the overload point of the sensor, i.e., the peak overload point of the sensor in response to a stimulus. Furthermore, the coil constant of coil 109 determines the magnitude of the output signal of the sensor in response to a given amount of acceleration in response to a stimulus, such as force. More specifically, the coil constant of coil 109 in conjunction with the values of 320A and 320B determine the output scale factor in Volts per unit of stimulus, e.g., g of acceleration.

The output of amplifier 345 feeds one end or terminal of coil 109 via resistors 315A and 320A. Conversely, the output of amplifier 355 feeds the other end of coil 109 via resistors 315B and 320B. Thus, amplifiers 345 and 355 provide a drive signal for coil 109 via resistors 315A-315B and 320A-320B.

MCU 310 may adjust (or calibrate or set or program or configure) the values of resistors 320A-320B. Note that the values of resistors 320A-320B affect the gain or scale factor of the sensor. In other words, the values of resistors 320A-320B determine the full range or scale that the sensor can sense, e.g., the full range of acceleration in response to the stimulus.

Note that although the exemplary embodiments of FIGS. 8-9 show MCU 310 as the controller, other possibilities exist and are contemplated. For example, a processor (e.g., a central processing unit (CPU) or other type of processor), a logic circuit, a finite-state machine, etc., may be used to control the values of the various resistors. The choice of the controller used depends on factors such as design and performance specifications, the degree of flexibility and programmability desired, the available technology, cost, etc., as persons of ordinary skill in the art will understand.

FIG. 10 illustrates the output signal 400 of a TIA 118 in an exemplary embodiment, for example, one of the embodiments of FIGS. 3 and 6-9. Output signal 400 shows how the output signal 400 (measured in Volts) of TIA 118 varies as a function of displacement, x (measured in meters). The output signal 400 shows a variation around a reference point 405 in response to displacement.

Thus, in the example shown, in response to a displacement x₁, having, for example, an absolute value of 100 nm around reference point 405 (say, ±100 nm), the output signal 400 varies from −V to +V, for example, by ±2 volts. The output signal 400 is a function of the gain of TIA 118. As noted above, the gain of TIA 118 determines the peak response or overload point of TIA 118.

Note that the output signal 400 of TIA 118 may be periodic (e.g., a cyclical interference fringe condition) in response to displacement, as persons of ordinary skill in the art will understand. FIG. 10 shows merely a portion of output signal 400 for the sake of discussion.

FIG. 11 shows a flow diagram 500 for a method of operating a sensor according to an exemplary embodiment. More specifically, the figure illustrates the actions that a controller, such as MCU 310, described above, may take, starting with the sensor's power-up.

After power-up, at 505 MCU 310 is reset. The reset of MCU 310 may be accomplished in a variety of ways. For example, a resistor-capacitor combination may hold the reset input of MCU 310 for a sufficiently long time to reset MCU 310. As another example, a power-on reset circuit external to MCU 310 may cause MCU 310 to reset. As another example, MCU 310 may be reset according to commands or control signals from a host.

After reset, MCU 310 begins executing firmware or user program instructions. The firmware or user program instructions may be included in a storage circuit within MCU 310 (e.g., internal flash memory) or in a storage circuit external to MCU 310 (e.g., an external flash memory). In any event, MCU 310 takes various actions in response to the firmware or user program instructions.

At 510, MCU 310 adjusts one or more resistors (e.g., resistors 305A-305B in FIG. 8 or resistor 305 in FIG. 9) to calibrate the gain of TIA 118 (see, for example, FIGS. 8 and 9). As described above in detail, the gain of TIA 118 affects certain attributes of the sensor.

At 515, MCU 310 adjusts resistors (e.g., resistors 320A-320B in FIGS. 8 and 9) in the signal path that drives coil 109 (see, for example, FIGS. 8 and 9). As described above in detail, the values of resistors 320A-320B affects certain attributes of the sensor, such as gain or scale of the sensor. Optionally, MCU 310 may make other adjustments or calibrations, for example, it may adjust the values of resistors 340 and 360 (see FIG. 9).

Referring again to FIG. 11, at 520 MCU 310 may optionally enter a sleep state. In the sleep state certain parts or blocks of MCU 310 may be disabled or powered down or placed in a low-power state (compared to when MCU 310 is powered up). Examples include placing the processor, input/output (I/O) circuits, signal processing circuits (e.g., ADC), and/or other circuits (e.g., arithmetic processing circuits) of MCU 310 in a sleep state.

Placing some of the circuitry of MCU 310 in a sleep state lowers the power consumption of MCU 310, in particular, and of the sensor, overall. Depending on the amount of power consumed in the sleep state and factors such as power-source capacity (e.g., the capacity of a battery used to power the sensor), MCU 310 may remain in the sleep state for relatively long periods of time, e.g., days, weeks, months, or even longer. Thus, the power savings because of the use of the sleep state provide a particular benefit in portable or remote applications where a battery may be used to power the sensor.

Note that some circuitry in MCU 310 may be kept powered up, even during the sleep mode or state. For example, a real-time clock (RTC) circuit (or other timer circuitry) may be kept powered and operational so as to track the passage of time. As another example, interrupt circuitry of MCU 310 may be kept powered and operation so that MCU 310 may respond to interrupts.

As part of entering the sleep state, the state of MCU 310 may be saved, for example, contents of registers, content of the program counter, etc. Saving the state of MCU 310 allows restoring MCU 310 later (e.g., when MCU 310 wakes up or resumes from the sleep state) to the same state as when it entered the sleep state.

MCU 310 may leave the sleep mode or state (wake up) and enter the normal mode of operation (e.g., processing signals generated in the sensor in response to a stimulus), or resume from the sleep state. For instance, in some embodiments, MCU 310 (or a CPU or other processor or controller) remains in the sleep state until one or more conditions are met, for example, the output signal (Out+−Out−) exceeding a preset threshold or value, or a timer generating a signal after a preset amount of time has elapsed, etc. In some embodiments, once the condition(s) is/are met, an interrupt may be generated to cause MCU 310 to leave the sleep state.

As part of the process of leaving the sleep state and entering the normal mode of operation, the state of MCU 310 may be restored (if the state was saved, as described above). Once MCU 310 leaves the sleep state, it can process signals generated in response to the stimuli, as described above.

In some embodiments, the sensor may be self-contained. In other words, the sensor, e.g., MCU 310, may include instructions for code that determine how the sensor responds to stimuli, how it processes the signals generated as a result of the application of the stimulus (e.g., log the signal values, and time/date information, as desired), etc. The sensor may also include a source of energy, such as a battery, to supply power to the various circuits of the sensor. Such embodiments may be suitable for operation in conditions where access to the sensor is limited or relatively difficult.

In other embodiments, the sensor may communicate with another device, component, system, or circuit, such as a host. FIG. 12 illustrates such an arrangement according to an exemplary embodiment.

Specifically, a sensor, such as the sensors depicted in FIGS. 3 and 6-9, includes a controller, such as MCU 310. Circuit arrangement 600 in FIG. 12 also includes a host (or device or component or system or circuit) 605. The sensor, specifically, the controller (MCU 310) communicates with host 605 via link 370.

In exemplary embodiments, link 370 may include a number of conductors, and facilitate performing a number of functions. In some embodiments, link 370 may constitute a multi-conductor cable or other or similar means of coupling. In some embodiments, link 370 may constitute a bus.

In some embodiments, link 370 may constitute a wireless link (e.g., the sensor and host 605 include receiver, transmitter, or transceiver circuitry that allow wireless communication via link 370 by using radio-frequency (RF) signals). Use of a wireless link provides the advantage of communication without using cumbersome electrical connections, and may allow arbitrary or desired locations for the sensor and host 605.

In some embodiments, link 370 may constitute an optical link. Use of an optical link allows for relatively low noise in link 370. In such a situation, the sensor and host 605 may include optical sources and/or receivers or detectors, depending on whether unidirectional or bidirectional communication is desired.

In some embodiments, link 370 provides a mechanism for supplying power to various parts of the sensor. The sensor may include one or more local regulators, as desired, to regulate or convert the power received from host 605 (or other source), for example, by changing the voltage level or increasing the load regulation, as desired.

In some embodiments, link 370 provides a mechanism for the sensor and host 605 to communicate a variety of signals. Examples include data signals, control signals, status signals, and handshaking signals (e.g., as used in information exchange protocols). As an example, link 370 provides a flexible mechanism by which the sensor may receive information (e.g., calibration information) from host 605.

As another example, the sensor may provide information, such as data corresponding to or derived from a stimulus applied to the sensors. Examples of such data include information regarding displacement, velocity, and/or acceleration. Using this mechanism, host 605 may record a log of the data using desired intervals.

In exemplary embodiments, link 370 provides a flexible communication channel by supporting a variety of types of signals, as desired. For example, in some embodiments, link 370 may be used to communicate analog signals. In other embodiments, link 370 may be used to communicate digital signals. In yet other embodiments, link 370 may be used to communicate mixed-signal information (both analog and digital signals).

In some embodiments, host 605 may constitute or comprise an MCU (or other processor or controller) (not shown). In such scenarios, MCU 310 in the sensor may be omitted or may be moved to host 605, as desired. As an alternative, in some embodiments, the MCU in host 605 may communicate with MCU 310 in the sensor.

One aspect of the disclosure relates to sensors with configurable or switchable coils. More specifically, in exemplary embodiments, sensor include a network of switchable coils suspended in a magnetic field (e.g., produced by magnet 112, as described above). As described below, the network of switchable coils includes a number of coils and a number of switches that may be switches in order to change the topology of the network of switchable coils. By doing so, one or more characteristics of the sensor may be configured (trimmed, programmed, varied, modified, adjusted, calibrated, etc.), as described below in detail.

FIG. 13 depicts a circuit arrangement 650 for such a sensor. As described above, the sensor in FIG. 13 includes coil 109 suspended in the magnetic field of one or more magnets 112. Optical position sensor 115 detects the movement of coil 109 in response to stimuli, such as acceleration. As described above, optical position sensor 115 generates an output signal, for example, a current or voltage, in response to the movement of coil 109.

Signal processing circuit 655 is coupled to coil 109 and optical position sensor 115 to form a negative feedback circuit, as described above. Thus, signal processing circuit 655 receives the output signal of optical position sensor 115, processes that signal, and then applies an output signal to coil 109, as described above.

Signal processing circuit 655 may include a variety of components, blocks, or circuits. FIGS. 8-9 show examples according to two exemplary embodiments. Thus, signal processing circuit 655 may include one or more TIAs (not shown), resistors (not shown), amplifiers (not shown), filtering or feedback circuits/networks, etc. Generally, a variety of signal processing circuits 655 are contemplated, and are not limited to the examples shown in FIGS. 8-9, as persons of ordinary skill in the art will understand.

An output of signal processing circuit 655 couples to and drives coil 109. By virtue of the negative feedback in the circuit, coil 109 produces a force such that the sensor operates according to a force-balance principle, as described above.

In the example shown, coil 109 includes two coils, 109A and 109B. Coils 109A-109B may be coupled in series or in parallel by using a number of switches (the number of switches depends on a number of factors, such as the type of switch available, as described below).

In the configuration shown in FIG. 13, coils 109A and 109B have been coupled in series (by using switches (not shown)). Given that the supply voltage of the sensor is finite (and typically limited, for example, to the voltage of a battery used in the field), the maximum available current (assuming negligible losses or voltage drops in other circuit components, such as transistors, amplifiers, etc.), I_max, flowing through coil 109 is given by:

$I_{ma x} = \frac{V_{s}}{R_{c}},$

where V_sand R_cdenote, respectively, the supply voltage of the sensor and the total coil resistance.

By using two coils coupled in series (e.g., by breaking up a coil 109 into two coil sections and coupling them in series), the total resistance of the coil has a maximum value. More specifically, compared to coupling the two coils in parallel, series-coupled coils have a higher overall resistance.

As noted above, given a supply voltage V_s, the maximum value of coil current, I_maxis limited by the overall coil resistance. Compared to a parallel configuration (described below in detail), the configuration shown in FIG. 13 results in a smaller coil current.

Assuming other parameters of the sensor (e.g., TIA gain, resistance values, etc.) are held constant, coupling coils 109A and 109B in series causes a number of characteristics of the sensor to change. For example, the sensor has higher sensitivity to stimuli, such as acceleration, and also higher scale factor (gain).

As noted above, coils 109A-109B may be switched into a parallel configuration. FIG. 14 illustrates a circuit arrangement 670 for the embodiment of FIG. 13 with the plurality of coils coupled in a parallel configuration (by using switches (not shown)).

Using two coils coupled in parallel (e.g., by breaking up a coil 109 into two coil sections, as described above) and coupling them in parallel) decrease the overall resistance of the coil. Specifically, compared to coupling the two coils in series, parallel-coupled coils have a lower overall resistance.

Given a supply voltage V_s, the maximum value of coil current, I_max, is limited by the overall coil resistance, as discussed above. Thus, compared to a series configuration (shown in FIG. 13), the configuration in FIG. 14 results in a larger coil current.

Assuming other parameters of the sensor (e.g., TIA gain, resistance values, etc.) are held constant, coupling coils 109A and 109B in parallel causes a number of characteristics of the sensor to change. For example, the sensor has a higher total coil current and thus a higher full-scale range.

As noted above, in exemplary embodiments, the topology of the overall coil (which may include two or more coils) of the sensor may be configured or changed (e.g., by changing the topology of a network of switchable coils). Given that the configuration of the coils affects sensor characteristics, as described above, changing the coil configuration allows configuration of the sensor characteristics.

Furthermore, by changing the coil configuration, one or more sensor characteristics corresponding to a given coil configuration may be traded off with one or more sensor characteristics corresponding to another coil configuration. For instance, referring to the example shown in FIGS. 13-14, using series-coupled coils 109A-109B provides a higher scale factor, compared to a higher full-scale range that results from using parallel-coupled coils 109A-109B. Thus, the two characteristics, scale factor and full-scale range, may be traded off by changing the topology of the network of switchable coils from series-coupled to parallel-coupled.

As noted above, in exemplary embodiments, two or more coils may be used. More specifically, a network of switchable coils may be used that includes two or more coils and a plurality of switches. By changing the topology of the network of switchable coils, the topology of the coil may be changed (the coil may be configured).

FIG. 15 shows a circuit arrangement 680 for a sensor with a network of switchable coils according to an exemplary embodiment. Specifically, the sensor in FIG. 15 includes coil switch network 690, which includes a plurality of coils and a plurality of switches 690. As such, coil switch network 690 constitutes a network of switchable coils. By changing the topology of coil switch network 690, the topology of the overall coil (e.g., series-coupled coils, parallel-coupled coils) of the sensor may be configured.

Similar to the embodiment in FIGS. 13-14, optical position sensor 115 detects the movement of the coil (as presented by coil switch network 690) in response to stimuli, such as acceleration. As described above, optical position sensor 115 generates an output signal, for example, a current or voltage, in response to the movement of the coil.

Signal processing circuit 655 is coupled to coil switch network 690 and optical position sensor 115 to form a negative feedback circuit, as described above. Thus, signal processing circuit 655 receives the output signal of optical position sensor 115, processes that signal, and then applies an output signal to the coils in coil switch network 690.

As noted above, signal processing circuit 655 may include a variety of components, blocks, or circuits, as desired. The output of signal processing circuit 655 couples to and the inputs or terminals of coil switch network 690 (denoted as A and B) to drive the coils in coil switch network 690. By virtue of the negative feedback in the circuit, the coils in coil switch network 690 produces a force such that the sensor operates according to a force-balance principle, as described above.

Coil switch network 690, described in more detail below, includes a plurality of coils and switches. By using controller 660, the switches in coil switch network 690 may be controlled. For example, by using controller 660, some of the switches in coil switch network 690 may be opened. As another example, by using controller 660, some of the switches in coil switch network 690 may be closed. As another example, by using controller 660, some of the switches in coil switch network 690 may be opened, whereas some of the switches in coil switch network 690 may be closed.

In some embodiments, the switches in coil switch network 690 are physically or mechanically switched (e.g., switched manually). In such embodiments, controller 660 may be omitted, and the user of the sensor may manually set the positions or state of the switches in coil switch network 69.

In some embodiments, the switches in coil switch network 690 are electronically controlled. In such embodiments, controller 660 controls the switches in coil switch network 690. Examples of such switches include electromechanical switches (e.g., relays, reed relays) and transistors (e.g., such as metal oxide semiconductor (MOS) transistors, bipolar junction transistor (BJT), etc.

In exemplary embodiments, coil switch network 690 may have a variety of topologies and arrangements. FIGS. 16-20 provides some examples of coil switch network 690.

More specifically, FIG. 16 depicts a coil switch network 690 with two coils 109A and 109B. Coil switch network 690 also includes switches SA and SB. Switches SA and SB are commonly controlled by controller 660. In other worse, switches SA and SB are configured as double-pole double-throw (DPDT) switch.

Coils 109A-109B may be coupled in series or in parallel, as desired. To couple coils 109A-109B in series, the wipers of switches SA and SB is placed (by controller 660) in the “up” position (i.e., the position shown in FIG. 16). In that position, switch SB couples coil 109A in series with coil 109B between points A and B. Switch SA does not affect the coil configuration, as its wiper is coupled to a switch terminal that is not coupled to another part of the circuit.

Conversely, cols 109A-109B may be coupled in parallel. To do so, the wipers of switches SA and SB is placed (by controller 660) in the “down” position (i.e., the opposite of the position shown in FIG. 16). In that position, switch SB couples coil 109B to point A. Also, switch SA couples coil 109A to point B. As a consequence, coils 109A-109B are coupled in parallel between points A and B.

Rather than using multi-throw switches, such as the switches in FIG. 16, other types of switch may be used, e.g., single-throw switches or single-pole single-throw (SPST) switches. FIGS. 17-20 provide examples of coil switch network 690 that use alternative switches.

Referring to FIG. 17, a coil switch network 690 according to an exemplary embodiment is illustrated. Coil switch network 690 includes coils 109A-109B, and four switches S1A-S1B and S2A-S2B. Controller 660 (not shown) controls switches S1A-S1B and S2A-S2B in order to provide a desired topology of coil switch network 690 and, thus, a desired coil configuration, to points A and B.

More specifically, by controlling switches S1A-S1B and S2A-S2B, coils 109A-109B may be coupled in series or in parallel. Table 1 shows the topology of coil switch network 690 as a function of the status (i.e., open and closed) of switches S1A-S1B:

TABLE 1

Configuration
S1A
S1B
S2A
S2B

coil 109A in series with
Open
Closed
Closed
Open

coil 109B

coil 109A in parallel with
Closed
Closed
Open
Closed

coil 109B

FIG. 18 depicts a coil switch network 690 according to another exemplary embodiment is illustrated. Coil switch network 690 includes coils 109A-109B, and three switches S1A-S1C. Controller 660 (not shown) controls switches S1A-S1C in order to provide a desired topology of coil switch network 690 and, thus, a desired coil configuration, to points A and B.

More specifically, by controlling switches S1A-S1C, coils 109A-109B may be coupled in series or in parallel. Table 2 shows the topology of coil switch network 690 as a function of the status (i.e., open and closed) of switches S1A-S1B:

TABLE 2

Configuration
S1A
S1B
S1C

coil 109A in series with
Open
Open
Closed

coil 109B

coil 109A in parallel with
Closed
Closed
Open

coil 109B

The coil switch networks shown in FIGS. 17-18 may be generalized to more than two coils, for example, N coils, where N represents a positive integer greater than two. FIGS. 19-20 provide examples of coil switch networks 690 with N coils according to exemplary embodiments.

FIG. 19 depicts a coil switch network 690 with N coils according to an exemplary embodiment. The coil switch network in FIG. 19 is a more general version (N coils) of the coil switch network shown in FIG. 17.

Coil switch network 690 includes coils 109A-109N, and switches S1A-S1N and S2A-S2N. Controller 660 (not shown) controls switches S1A-S1N and S2A-S2N in order to provide a desired topology of coil switch network 690 and, thus, a desired coil configuration, to points A and B.

By controlling switches S1A-S1N and S2A-S2, two or more of coils 109A-109N may be coupled in series or in parallel. For example, to couple coils 109A-109C in series, switches S1B, S2A, S2B, and SNB are closed, but switches S1A, S2B, and SNA are opened. As another example, to couple coils 109B-109C in parallel, switches S1A, S2A, S2B, S3B, and SNB are closed, and switches S1B, S3A, and SNA are opened. A variety of other switch configurations and, thus, coil configurations presented at points A and B, are possible.

FIG. 20 illustrates a coil switch network 690 with N coils according another exemplary embodiment. The coil switch network in FIG. 20 is a more general version (N coils) of the coil switch network shown in FIG. 18.

Also, the coil switch network in FIG. 20 is similar to the coil switch network shown in FIG. 19, but adds switches S1C, S2C, etc. The additional switches (S1C, S2C, etc.) provide more flexibility in coupling two or more of coils 109A-109N in series or parallel.

Similar to FIG. 19, by controlling the switches in FIG. 20, two or more of coils 109A-109N may be coupled in series or in parallel. For example, to couple coils 109A and 109C in series, switches S1C, S2A, S2B, and SNB are closed, but switches S1A, S1B, S2B, S2C, S3A, and SNA are opened. As another example, to couple coils 109B-109C in parallel, switches S1A, S2A, S2B, S3B, and SNB are closed, and switches S1B, S1C, S2C, S3A, and SNA are opened. A variety of other switch configurations and, thus, coil configurations presented at points A and B, are possible.

In the embodiments shown, controller 660 controls various switches. Other arrangements, however, are contemplated and may be used. For example, a controller, either in the sensor or in a remote location (e.g., a remote host, such as host 605 in FIG. 12) may control the switches. As noted above, as another example, the switches may be manually controlled by a user, e.g., by setting each switch to the desired position.

As yet another example, MCU 310 (see, for example, FIGS. 8-9) may be used to control the states of the switches. In some embodiments, MCU 310 may include information, such as instructions or commands, to control the switch states. In some embodiments, MCU 310 may obtain information (e.g., from host 605 or another source), such as instructions or commands, to control the switch states.

Although sensors according to exemplary embodiments have been described and illustrated in the accompanying drawings, a variety of other embodiments and arrangements are contemplated. The following description provides some examples.

In some embodiments, MCU 310 may be omitted. Instead, a remote host, device, component, system, circuit, etc., may couple to circuitry in the sensor to perform various operations, e.g., adjust the values of the various resistors. The sensor may include circuitry to facilitate communication with the remote host. Analog, digital, or mixed-signal control communication signals may be used to adjust the resistor values, as desired.

In some embodiments, the electrical components (e.g., MCU 310, TIA 118, etc.) and rest of the sensor components (e.g., coil, optical position sensor) reside in the same housing. In other embodiments, the electrical components and rest of the sensor components reside in different components (e.g., to allow easier access to some components, while protecting other components) of the same housing.

In yet other embodiments, the electrical components and rest of the sensor components, for example, the coil and/or optical position sensor, reside in different or separate housings. The choice of configuration depends on a variety of factors, as persons of ordinary skill in the art will understand. Examples of such factors include design and performance specifications, the intended physical environment of the sensor, the level of access desired to various components, cost, complexity, etc.

Sensors according to exemplary embodiments may be used in a variety of applications. For example, sensors according to some embodiments may be used for geological exploration. As another example, sensors according to some embodiments may be used for detecting seismic movement, i.e., in seismology. As another example, sensors according to some embodiments may be used for detecting and/or deriving various quantities related to navigation, i.e., in inertial navigations. Other applications include using the sensor as a reference sensor for motion stimulus testing of other components or sensors under test.

Referring to the figures, persons of ordinary skill in the art will note that the various blocks shown might depict mainly the conceptual functions and signal flow. The actual circuit implementation might or might not contain separately identifiable hardware for the various functional blocks and might or might not use the particular circuitry shown. For example, one may combine the functionality of various blocks into one circuit block, as desired. Furthermore, one may realize the functionality of a single block in several circuit blocks, as desired. The choice of circuit implementation depends on various factors, such as particular design and performance specifications for a given implementation. Other modifications and alternative embodiments in addition to those described here will be apparent to persons of ordinary skill in the art. Accordingly, this description teaches those skilled in the art the manner of carrying out the disclosed concepts, and is to be construed as illustrative only. Where applicable, the figures might or might not be drawn to scale, as persons of ordinary skill in the art will understand.

The forms and embodiments shown and described should be taken as illustrative embodiments. Persons skilled in the art may make various changes in the shape, size and arrangement of parts without departing from the scope of the disclosed concepts in this document. For example, persons skilled in the art may substitute equivalent elements for the elements illustrated and described here. Moreover, persons skilled in the art may use certain features of the disclosed concepts independently of the use of other features, without departing from the scope of the disclosed concepts.

	Number	Date	Country
	61712652	Oct 2012	US
	61721903	Nov 2012	US

	Number	Date	Country
Parent	PCT/US2013/032584	Mar 2013	US
Child	14520840		US

Apparatus for Sensor with Configurable Coil and Associated Methods

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