Optical sensor device for detecting a pulse of a living body

The invention claimed is: 1. An optical sensor device comprising: a light emitter configured to periodically emit light at a predetermined frequency toward a measurement target; a light receiver configured to detect at least one of reflected light and diffused light from the measurement target, and to output an electrical signal based on the detected light; a filter circuit configured to filter the electrical signal at the predetermined frequency and to output a modulation signal; an amplifier configured to amplify the modulation signal; an AD converter configured to convert the modulation signal to a digital signal; and an arithmetic processing unit coupled to the AD converter and configured to calculate a DC component of the electrical signal based on the digital signal by: calculating a total DC component based on both extraneous light noise and the detected light by employing a signal contained in the modulation signal and obtained during an on-period of the light emitter, calculating a DC component attributable to the extraneous light noise by employing a signal contained in the modulation signal and obtained during an off-period of the light emitter, and calculating the DC component attributable to the detected light by excluding the DC component attributable to the extraneous light noise from the calculated total DC component, wherein the arithmetic processing unit is further configured to calculate an AC component of the electrical signal by excluding the DC component from the modulation signal. 2. The optical sensor device according to claim 1 , wherein the filter circuit comprises a frequency band that corresponds to a portion of the electrical signal. 3. The optical sensor device according to claim 1 , wherein the light emitter comprises: a first light emitting element configured to emit light in a first wavelength band at the predetermined frequency; and a second light emitting element configured to emit light in a second wavelength band at the predetermined frequency, the second wavelength band being different than the first wavelength band. 4. The optical sensor device according to claim 3 , wherein the first and second light emitting elements are configured to concurrently emit light at the predetermined frequency. 5. The optical sensor device according to claim 3 , wherein the first and second light emitting elements are configured to alternately emit light at the predetermined frequency. 6. The optical sensor device according to claim 3 , wherein the light receiver is further configured to detect light in both the first and second wavelength bands and to output a first electrical signal and a second electrical signal corresponding to light emitted from the first and second light emitting elements, respectively. 7. The optical sensor device according to claim 6 , wherein the arithmetic processing unit is further configured to calculate an absorbance ratio of the measurement target based on a ratio of a first ratio between an amplitude of a first AC component and a first DC component calculated from the first electrical signal, to a second ratio between an amplitude of a second AC component and a second DC component calculated from the second electrical signal. 8. The optical sensor device according to claim 1 , further comprising: a separation circuit including the filter circuit and configured to separate the modulation signal and the DC component of the electrical signal, wherein the AD converter is further configured to convert the DC component of the electrical signal to a DC component digital signal, and wherein the arithmetic processing unit is further configured to convert the modulation signal and the DC component digital signal based on an amplification factor of the amplifier, such that an amplitude ratio between the modulation signal and the DC component digital signal reaches a state before the amplification by the amplifier, and to calculate the AC component of the electrical signal based on the modulation signal. 9. The optical sensor device according to claim 8 , wherein the arithmetic processing unit is further configured to calculate the DC component attributable to extraneous light noise based on a signal contained in the DC component of the electrical signal and obtained during an off-period of the light emitter. 10. An optical sensing method comprising: emitting light, by a light emitter, at a predetermined frequency towards a measurement target; detecting, by a light receiver, at least one of reflected light and diffused light from the measurement target; outputting, by the light receiver, an electrical signal based on the detected light; filtering, by a filter circuit, the electrical signal at the predetermined frequency; outputting, by the filter circuit, a modulation signal corresponding to the filtered electrical signal; amplifying, by an amplifier, the modulation signal; converting, by an AD converter, the amplified modulation signal to a digital signal; calculating, by a processor, a DC component and an AC component of the electrical signal based on the digital signal, wherein the DC component of the electrical signal is calculated by determining a time-average value of the modulation signal and the AC component of the electrical signal is calculated by excluding the DC component from the modulation signal; calculating, by the processor, a total DC component based on both extraneous light noise and the detected light by employing a signal contained in the modulation signal and obtained during an on-period of the light emitter; calculating, by the processor, a DC component attributable to the extraneous light noise by employing a signal contained in the modulation signal and obtained during an off-period of the light emitter; and calculating, by the processor, the DC component attributable to the detected light by excluding the DC component attributable to the extraneous light noise from the calculate total DC component. 11. The optical sensing method according to claim 10 , further comprising: separating, by a separation circuit including the filter circuit, the modulation signal and the DC component of the electrical signal; converting, by the AD converter, the DC component of the electrical signal to a DC component digital signal; converting, by the processor, the modulation signal and the DC component digital signal based on an amplification factor of the amplifier, such that an amplitude ratio between the modulation signal and the DC component digital signal reaches a state before the amplification by the amplifier; and calculating, by the processor, the AC component of the electrical signal based on the modulation signal. 12. The optical sensing method according to claim 11 , further comprising calculating, by the processor, the DC component attributable to extraneous light noise based on a signal contained in the DC component of the electrical signal and obtained during an off-period of the light emitter. 13. The optical sensing method according to claim 10 , wherein the step of emitting light further comprises: emitting, by a first light emitting element of the light emitter, light in a first wavelength band at a predetermined frequency towards the measurement target; and emitting, by a second light emitting element of the light emitter, light in a second wavelength band at the predetermined frequency towards the measurement target, wherein the step of outputting the electrical signal comprises outputting, by the light receiver, first and second electrical signal based on the detected light in the first and second wavelength bands, respectively, and wherein the step o