Thermal marking systems and methods of control

The invention claimed is: 1. A target marking system, comprising: a light source configured to emit a beam of thermal radiation and to impinge the beam onto a target; and a detector having a plurality of thermal radiation sensitive pixels that can be scanned to obtain signals that are used to form a thermal image of a field of view, with the detector being configured to collect thermal radiation passing from the field of view to the detector including radiation passing from the target in response to the beam impinging the target; wherein the light source is energized during a time period in which the detector scans thermal radiation sensors corresponding a portion of the field of view likely to be impinged upon by the emitted beam of the target marking system and wherein the light source does not emit a beam of thermal radiation during scanning of at least one other thermal radiation sensitive pixel outside during scanning outside of the portion of the field of view likely to be impinged upon by the emitted thermal beam. 2. The target marking system of claim 1 , wherein the detector comprises an array of thermal radiation pixels arranged in a row and wherein the light source is energized during a time period in which the detector scans one or more rows of the thermal radiation sensitive pixels within which the thermal radiation corresponding to the portion of the field of view likely to be impinged upon by the emitted beam will be detected. 3. The target marking system of claim 1 , further comprising a visible light display and an input with a selectively engageable outline mode in which the image includes only a perimeter corresponding to each respective object within a field of view of the detector, each perimeter being determined at least in part by relative differences in levels of radiation emitted by each respective object. 4. The target marking system of claim 1 , further comprising a visible light display adapted to present a visible light image of the field of view having a representation of the thermal beam impinging the target that occupies a greater portion of visible light field of view than a portion of the thermal image occupied by radiation passing from the field of view. 5. A target marking system, comprising: a light source configured to emit a beam of thermal radiation and to impinge the beam onto a target; a detector configured to collect radiation passing from the target to the detector, the radiation passing from the target in response to the beam impinging the target, the detector comprising at least one lens focusing thermal radiation to form a thermal radiation image of a field of view on an array of thermal radiation sensitive pixels arranged in a plurality of rows and being operable to capture an image of thermal radiation in the field of view by scanning the rows of thermal sensors during a period of time; wherein the duty cycle of the light source is configured so that the emitted beam is only generated during a time period where the one or more rows on which an area of the field of view depicting the target impinged upon by the emitted beam is focused. 6. The target marking system of claim 5 , wherein the plurality of thermal radiation sensitive pixels comprise a plurality of thermal radiation sensors. 7. The target marking system of claim 5 , further including a display configured to receive a signal from the detector and to display a visible light image that is representative of the thermal image. 8. The target marking system of claim 5 , wherein the lens increases a resolution of the image such that the point of impact of the beam on the target can be distinguished from the target in the image. 9. A method of controlling a target marking system, comprising: emitting a beam of thermal radiation; collecting radiation from a field of view including a target against which the thermal beam of radiation impinges, with the collected radiation passes from the target, along a path, in response to the beam impinging upon the target; and using the collected radiation to form an image of the field of view on a plurality of thermal radiation sensitive pixels; wherein the beam of thermal radiation is generated during a time period in which the detector scans thermal radiation pixels corresponding a portion of the field of view likely to be impinged upon by the emitted beam of the target marking system and wherein the beam of thermal radiation is not directed to emit a beam of thermal radiation at least in part of a time period in which the detector scans thermal radiation pixels not corresponding to the identified area. 10. The method of claim 9 , further comprising magnifying the collected radiation and narrowing a field of view to an extent necessary to discriminate a portion of the field of view having a thermal beam impinging thereon and other portions of the field of view. 11. The method of claim 10 , further comprising presenting a representation of the thermal image in visible light. 12. The method of claim 11 , further comprising, further comprising presenting a representation of the thermal image in visible light in the form of an outline mode in which the image includes only a perimeter corresponding to each respective object within a field of view of the detector, each perimeter being determined at least in part by relative differences in levels of radiation emitted by each respective object. 13. The target marking system of claim 9 , further comprising presenting a visible light image of the field of view having a representation of the thermal beam impinging the target that occupies a greater portion of visible light field of view than a portion of the thermal image occupied by radiation passing from the field of view.