An optical sensor for an instrument to form a closed-loop curing instrument that is configured to manage the quantity of delivered energy to a curable material, including a composite restoration for a tooth. The closed-loop curing instrument is configured to analyze a signal indicative of the light
An optical sensor for an instrument to form a closed-loop curing instrument that is configured to manage the quantity of delivered energy to a curable material, including a composite restoration for a tooth. The closed-loop curing instrument is configured to analyze a signal indicative of the light reflecting from the curable material, and to adjust light output based on the analysis.
대표청구항▼
1. A dental curing instrument for curing a target, the target including a restorative material that is curable in response to application of light energy, the dental curing instrument comprising: a light source capable of outputting the light energy to cure the restorative material, the light source
1. A dental curing instrument for curing a target, the target including a restorative material that is curable in response to application of light energy, the dental curing instrument comprising: a light source capable of outputting the light energy to cure the restorative material, the light source being controllable to vary the light energy being output;a light sensor for sensing a light energy characteristic;an optical feedback path operable coupled to the light sensor, the optical feedback path being disposed to channel light reflected back from the target to the light sensor, wherein the light sensor is configured to sense the light energy characteristic with respect to the light reflected back from the target; anda controller operably coupled to the light sensor and the light source, the controller configured to vary, based on the light energy characteristic sensed by the light sensor, an operating characteristic of the light source from a first operating characteristic to a second operating characteristic to affect the light energy being output from the light source, wherein the light source is configured to output light based on operation at the first operating characteristic, wherein the light source is configured to output light based on operation at the second operating characteristic. 2. The dental curing instrument according to claim 1 wherein the optical feedback path is aligned with an illumination beam of light of the light source being output from the dental curing instrument such that the optical feedback path is within the illumination beam. 3. The dental curing instrument according to claim 2 wherein the optical feedback path is coaxially aligned with the illumination beam. 4. The dental curing instrument according to claim 3 wherein the light sensor is positioned to substantially avoid shadowing the illumination beam. 5. The dental curing instrument according to claim 1 wherein the optical feedback path and the light sensor form isolated optical feedback to the controller, wherein the controller is configured to assess, in real time, an actual light intensity (mW/cm2) delivered to a surface of the target, wherein the assessment is independent from operator induced variation caused by at least one of distance or angle of presentation of the dental curing instrument with respect to the target. 6. The dental curing instrument according to claim 1 wherein the light sensor provides a real time intensity optical sensor feedback signal, wherein the controller, based on the optical sensor feedback signal, produces corrective adjustments by controlling a light source intensity of the light source, whereby the controller stabilizes an actual light intensity delivered to a surface of the target. 7. The dental curing instrument of claim 6 wherein the controller is programmed to further use the optical sensor feedback signal as a basis for determining a time integral of an optical intensity on the target, the controller being programmed to compute, in real time, an actual total energy delivered to the surface of the target. 8. The dental curing instrument of claim 7 wherein the actual total energy is expressed in terms of energy in Joules/cm2 equaling intensity in w/cm2*tsec. 9. The dental curing instrument of claim 8 wherein the controller uses the real time computation of Joules/cm2 as a basis for controlling the light source to control an amount of energy delivered by further managing a time of active exposure. 10. The dental curing instrument of claim 1 wherein the optical feedback path is shared with a light delivery path through which the light source outputs energy to the target, wherein the controller is programmed to differentially and ratiometrically assess the light energy output from the light source and the light reflected back from the target, wherein signals indicative of the light energy output and the light reflected back are obtained from within the shared light delivery path. 11. The dental curing instrument of claim 1 further comprising Built In Diagnostics (BIT) based on the light energy characteristic. 12. The dental curing instrument of claim 11 wherein the BIT includes capabilities to detect at least one of light source issues, battery issues and tip contamination. 13. The dental curing instrument of claim 1 wherein the controller is configured to confirm that the target is present in a path of light energy output from the light source when a curing operation is being activated by a button, and in response to determining that the target is not present, deactivating the light source. 14. The dental curing instrument of claim 1 wherein the controller is programmed to determine presence and deactivate the light source in a timeframe on the order of microseconds. 15. The dental curing instrument of claim 1 wherein the target is a tooth or an opaque object. 16. A curing instrument for curing a light-curable material, said curing instrument comprising: a light source configured to generate light energy to cure the light-curable material, said light source configured to provide an illumination beam of light energy to the light-curable material;optical drive circuitry operably coupled to said light source, said optical drive circuitry configured to provide a power signal to said light source to generate said light energy, wherein said optical drive circuitry is configured to vary one or more operating characteristics of said power signal to vary output of light energy from said light source;a controller operably coupled to said optical drive circuitry, said controller configured to control operation of said optical drive circuitry to control generation of said light energy from said light source;an optical feedback sensor arranged to collect light reflected from the light-curable material, said optical feedback sensor having a light input with an optical sense path directed to the light-curable material, wherein said optical sense path of said light input is surrounded by said illumination beam generated from said light source; anda light sensor optically coupled to said light input of said optical feedback sensor, said light sensor is configured to generate an optical sensor feedback signal based on said light collected by said light input, wherein said controller directs said optical drive circuitry to vary, based on said optical sensor feedback signal, at least one of said one or more operating characteristics from a first operating characteristic to a second operating characteristic to vary output of light energy from said light source, wherein said light source is configured to output light based on operation at said first operating characteristic, wherein said light source is configured to output light based on operation at said second operating characteristic. 17. The curing instrument of claim 16 wherein said optical sense path is coaxially aligned with said illumination beam of light energy, wherein said light sensor is arranged relative to said light source to substantially avoid significant shadowing of said illumination beam. 18. The curing instrument of claim 16 further comprising a gas channel coupled to a gas nozzle that directs gas over the light-curable material to affect a temperature of the light-curable material, said gas channel forming at least part of a coolant system.
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