Fluorescence-imaging apparatus

The invention claimed is: 1. A fluorescence-imaging apparatus comprising: a light source configured to generate illumination light and excitation light to be radiated onto a subject; and a processor comprising hardware, wherein the processor is configured to implement: a fluorescence-image generating section configured to generate a fluorescence image by image-capturing fluorescence generated by the subject by irradiation with the excitation light from the light source; a return-light-image generating section configured to generate a return-light image by image-capturing return light that returns from the subject by irradiation with the illumination light from the light source; a fluorescence-image correcting section configured to generate a corrected fluorescence image in which luminance values of pixels are normalized by dividing the luminance values of the pixels of the fluorescence image generated by the fluorescence-image generating section by the luminance values of the pixels of the return-light image generated by the return-light-image generating section; and an error-image identifying section configured to: standardize image-acquisition conditions for the return-light image generated by the return-light-image generating section; identify an error region, which is a region in which the luminance values of the corrected fluorescence image exceed a preset allowable error range, on the basis of a gray level of the normalized return-light image; and control a display to display the error region. 2. The fluorescence-imaging apparatus according to claim 1 , wherein the error-image identifying section implemented by the processor is configured to identify the error region by using an area of a region having a high gray level in the normalized return-light image. 3. The fluorescence-imaging apparatus according to claim 1 , wherein the error-image identifying section implemented by the processor is configured to control the display to display the return-light image generated by the return-light-image generating section and the error region so as to be superimposed on the return-light image generated by the return-light-image generating section. 4. The fluorescence-imaging apparatus according to claim 3 , wherein the error-image identifying section implemented by the processor is configured to control the display to display the error region in a color different from that around the error region. 5. The fluorescence-imaging apparatus according to claim 1 , wherein if the error region is identified by the error-image identifying section, the error-image identifying section controls the display to display an error indication on a screen. 6. The fluorescence-imaging apparatus according to claim 1 , wherein the error-image identifying section implemented by the processor is configured to identify the error region on the basis of a gray level of a peripheral region in the normalized return-light image. 7. The fluorescence-imaging apparatus according to claim 1 , wherein the error-image identifying section implemented by the processor is configured to identify the error region on the basis of gray levels of a peripheral region and a central region in the normalized return-light image. 8. The fluorescence-imaging apparatus according to claim 1 , wherein the error-image identifying section implemented by the processor is configured to identify the error region on the basis of a gray level of a region corresponding to a vicinity of an emitting end of the illumination light in the normalized return-light image. 9. The fluorescence-imaging apparatus according to claim 1 , further comprising: an elongated scope; and an error-identification-condition storage provided in the elongated scope, wherein the error-identification-condition storage is configured to store an error identification condition serving as a reference for the error region, wherein the error-image identifying section implemented by the processor is configured to: read out the error identification condition from the error-identification-condition storage; and identify the error region based on the error identification condition read out from the error-identification-condition storage. 10. The fluoroscopy apparatus according to claim 1 , further comprising: an elongated scope; a scope-information storage provided in the elongated scope, wherein the scope-information storage is configured to store information about the elongated scope; and an error-identification-condition storage configured to store a plurality of error identification conditions serving as a reference for the error region, wherein the error-image identifying section implemented by the processor is configured to: read out the error identification conditions stored in the error-identification-condition storage based on the information stored in the scope-information storage; and identify the error region based on the error identification conditions read out from the error-identification-condition storage.