Endoscope system, processor device, and method for operating endoscope system

What is claimed is: 1. An endoscope system comprising: a light source device that generates illumination light to irradiate an observation object and is able to control an optical spectrum of the illumination light; an image sensor which includes a blue pixel receiving light in a blue wavelength band, a green pixel receiving light in a green wavelength band, a red pixel receiving light in a red wavelength band, and a white pixel receiving at least light in a blue wavelength band and a green wavelength light, and images the observation object by reflected light of the illumination light from the observation object; an imaging distance calculator which calculates an imaging distance which is a distance between the image sensor and the observation object; a light source controller which increases a component of the blue wavelength band or the green wavelength band included in the illumination light according to the imaging distance; and a demosaic processor configured to apply a first demosaic process performed with use of an image signal from the white pixel as a green image signal and a second demosaic process performed with use of an image signal from the white pixel as a blue image signal, the demosaic processor selectively applying the first demosaic process and the second demosaic process according to the imaging distance to an image signal which the image sensor outputs, wherein signal value of the white pixel is used as the green image signal of the white pixel position in the first demosaic process, and is used as the blue image signal of the white pixel position in the second demosaic process, and wherein the imaging distance calculator and the demosaic processor are implemented by a processor device. 2. The endoscope system according to claim 1 , wherein the light source controller increases the component of the green wavelength band included in the illumination light as the imaging distance becomes longer and keeps the component of other wavelength bands in the illumination light at a fixed intensity level. 3. The endoscope system according to claim 1 , wherein the light source controller increases the component of the blue wavelength band included in the illumination light as the imaging distance becomes shorter and keeps the component of other wavelength bands in the illumination light at a fixed intensity level. 4. The endoscope system according to claim 3 , wherein the light source controller decreases the component of the green wavelength band included in the illumination light as the imaging distance becomes shorter and keeps the component of other wavelength bands in the illumination light at a fixed intensity level. 5. The endoscope system according to claim 3 , wherein the light source controller decreases the component of the red wavelength band included in the illumination light as the imaging distance becomes shorter and keeps the component of other wavelength bands in the illumination light at a fixed intensity level. 6. The endoscope system according to claim 1 , further comprising a judgment section which compares the imaging distance with a predetermined threshold value, judges that the imaging distance is short in case the imaging distance is shorter than the threshold value, and judges that the imaging distance is long in case the imaging distance is longer than the threshold value, wherein in case the judgment section judges that the imaging distance is long, the light source controller increases the component of the green wavelength band included in the illumination light, and the demosaic processor applies the first demosaic process to the image signal output from the image sensor, and in case the judgment section judges that the imaging distance is short, the light source controller increases the component of the blue wavelength band included in the illumination light, and the demosaic processor applies the second demosaic process to the image signal output from the image sensor. 7. The endoscope system according to claim 1 , further comprising an exposure setting value calculator which calculates an exposure setting value to control an exposure amount when the observation object is imaged, based on image signals which the image sensor outputs, wherein the imaging distance calculator calculates the imaging distance based on the exposure setting value. 8. The endoscope system according to claim 1 , further comprising a gain controller that controls a gain when the image sensor outputs image signals, wherein the imaging distance calculator calculates the imaging distance based on the gain. 9. The endoscope system according to claim 1 , further comprising an imaging optical system in which an imaging magnification is variable, wherein the imaging distance calculator calculates the imaging distance based on the imaging magnification. 10. A method for operating an endoscope system which includes a light source device which generates illumination light to irradiate an observation object and is able to control an optical spectrum of the illumination light, and an image sensor which has a blue pixel receiving light in a blue wavelength band, a green pixel receiving light in a green wavelength band, a red pixel receiving light in a red wavelength band, and a white pixel receiving at least light in a blue wavelength band and a green wavelength light, and images the observation object by reflected light of the illumination light from the observation object, the method comprising: an imaging distance calculation step in which an imaging distance calculator calculates an imaging distance which is a distance between the image sensor and the observation object; a source-controlling step in which a light source controller increases a component of the blue wavelength band or the green wavelength band included in the illumination light based on the imaging distance; and a demosaic process step in which a demosaic processor applies a first demosaic process performed with use of an image signal from the white pixel as a green image signal and a second demosaic process performed with use of an image signal from the white pixel as a blue image signal, the demosaic processor selectively applying the first demosaic process and the second demosaic process according to the imaging distance to an image signal which the image sensor outputs, wherein signal value of the white pixel is used as the green image signal of the white pixel position in the first demosaic process, and is used as the blue image signal of the white pixel position in the second demosaic process, and wherein the imaging distance calculator and the demosaic processor are implemented by a processor device. 11. A processor device being used for an endoscope system which includes a light source device which generates illumination light to irradiate an observation object and is able to control an optical spectrum of the illumination light, and an image sensor which has a blue pixel receiving light in a blue wavelength band, a green pixel receiving light in a green wavelength band, a red pixel receiving light in a red wavelength band, and a white pixel receiving at least light in a blue wavelength band and a green wavelength light, and images the observation object by reflected light of the illumination light from the observation object, the light source device including a light source controller that increases a component of the blue wavelength band or the green wavelength band included in the illumination light based on an imaging distance, the processor device comprising: an imaging distance calculator which calculates an imaging distance which is a distance between the image sensor and the observation object; a dem