Vehicular lighting device

What is claimed is: 1. An abnormality detector for a light source, the light source being furnished with a laser diode for emitting excitation light, and a phosphor for emitting fluorescent light by undergoing excitation by the excitation light, wherein the light source is configured to generate white output light containing the excitation light and fluorescent light spectra, abnormality detector comprising: a first photosensor structured to be sensitive to the excitation light's wavelength and to be substantially insensitive to the fluorescent light's wavelength, and to receive a part of the output light so as to generate a first current that corresponds to an amount of received light; a second photosensor structured to be sensitive to the fluorescent light's wavelength, to be substantially insensitive to the excitation light's wavelength, and to receive a part of the output light so as to generate a second current that corresponds to an amount of received light; a first current/voltage conversion circuit comprising a first resistor arranged in a path of the first current, and structured to output a first detection voltage that corresponds to a voltage drop across the first resistor; and a second current/voltage conversion circuit comprising a second resistor arranged in a path of the second current, and structured to output a second detection voltage that corresponds to a voltage drop across the second resistor; and a judgment unit structured to assert an abnormality detection signal (i) if a relation between magnitudes of the 5 first detection voltage and the second detection voltage has reversed, or otherwise (ii) if the first detection voltage deviates from a voltage range in which the first detection voltage can be obtained at normal times. 2. The abnormality detector according to claim 1 , wherein, (iii) when the second detection voltage deviates from a voltage range in which the second detection voltage can be obtained at normal times, the judgment unit asserts the abnormality detection signal. 3. The abnormality detector according to claim 1 , wherein the voltage range boundaries are generated by dividing a power supply voltage supplied to the abnormality detector. 4. The abnormality detector according to claim 1 , wherein the judgment unit is structured to offset at least one from between the first detection voltage and the second detection voltage so as to increase a difference between them, and to monitor a magnitude relation between the first and second detection voltages thus offset. 5. The abnormality detector according to claim 1 , wherein: the first current/voltage conversion circuit and the second current/voltage conversion circuit are each configured as an inverting converter; the first photosensor comprises a first photodiode, the second photosensor comprises a second photodiode, wherein the first photodiode and the second photodiode are configured in the form of a single photodiode module; the photodiode module comprises the first photodiode and the second photodiode arranged such that cathodes thereof are coupled so as to form a common cathode, a first anode terminal coupled to an anode of the first photodiode, a second anode terminal coupled to an anode of the second photodiode, a cathode terminal coupled to the common cathode, and a metal casing structured to be electrically insulated from the cathode terminal, the first anode terminal, and the second anode terminal; and the photodiode module is housed in a CAN package. 6. A vehicular lighting device comprising: a light source; and the abnormality detector according to claim 1 , structured to detect an abnormality in the light source. 7. The abnormality detector according to claim 1 , wherein: the first photosensor comprises a first photodiode, the second photosensor comprises a second photodiode, wherein the first photodiode and the second photodiode are configured as a single photodiode module, the photodiode module comprising: the first photodiode and the second photodiode arranged such that cathodes thereof are coupled so as to form a common cathode; a first anode terminal coupled to an anode of the first photodiode; a second anode terminal coupled to an anode of the second photodiode; a cathode terminal coupled to the common cathode; and a metal casing structured to be electrically insulated from the first anode terminal, the second anode terminal, and the cathode terminal; wherein the photodiode module is housed in a CAN package. 8. An abnormality detector for a light source, the light source being furnished with a laser diode for emitting excitation light, and a phosphor for emitting fluorescent light by undergoing excitation by the excitation light, wherein the light source is configured to generate white output light containing the excitation light and fluorescent light spectra, the abnormality detector comprising: a first photosensor structured to be sensitive to the excitation light's wavelength and to be substantially insensitive to the fluorescent light's wavelength, and to receive a part of the output light so as to generate a first current that corresponds to an amount of received light; a second photosensor structured to be sensitive to the fluorescent light's wavelength, to be substantially insensitive to the excitation light's wavelength, and to receive a part of the output light so as to generate a second current that corresponds to an amount of received light; a first current/voltage conversion circuit comprising a first resistor arranged in a path of the first current, and structured to output a first detection voltage that corresponds to a voltage drop across the first resistor; and a second current/voltage conversion circuit comprising a second resistor arranged in a path of the second current, and structured to output a second detection voltage that corresponds to a voltage drop across the second resistor; and a judgment unit structured to assert an abnormality detection signal (i) if a relation between magnitudes of the first detection voltage and the second detection voltage has reversed, or otherwise (iii) if the second detection voltage deviates from a voltage range in which the second detection voltage can be obtained at normal times.