Optical measurement apparatus and optical measurement method

What is claimed is: 1. A method for performing optical measurement, comprising: directing light from a light generator to a light path cell; generating a light path by continuously reflecting the light directed from the light generator between first and second high reflection mirrors of the light path cell that face each other; detecting an optical signal from an aerosol sample present within the light path, the aerosol sample including a gas and solid and/or liquid particles suspended within the gas; separating the optical signal into a particle signal representing the solid and/or liquid particles suspended in the gas and a gas signal representing the gas by using a statistical methodology; calculating a particle concentration representing the solid and/or liquid particles suspended in the gas from the particle signal by using an assumption about characteristics of the solid and/or liquid particles for implementing an optical particle counter (OPC); and calculating a gas concentration representing the gas from the gas signal by using optical characteristic data of gas, wherein the calculating of the particle concentration representing the solid and/or liquid particles suspended in the gas and the calculating of the gas concentration are performed simultaneously, and wherein separating the optical signal into the particle signal and the gas signal includes expressing a light intensity as an extinction coefficient using the Beer-Lambert Law and separating the particle signal and the gas signal by using algebraic and statistical methodologies. 2. The method of claim 1 , wherein the assumption of the optical particle counter includes conditions that all particles are spherical, all particles have a density of 1 g/cm 3 , and all particles have optical refraction and absorption constants (m=n+ki), where m is a refractive index, n determines speed of light within a medium, k is an attenuation coefficient indicating attenuation of light, and i is an intensity of light. 3. The method of claim 1 , further comprising: calculating an optical characteristic of a particle from the particle signal by using particle concentration data measured by a particle counting device; and calculating an optical characteristic of the gas from the gas signal by using gas concentration data measured by a gas concentration measuring device. 4. The method of claim 1 , wherein the light generator generates the light of a preset wavelength according to a type of a particle to be measured, and wherein the light of the preset wavelength includes ultraviolet (UV) light, visible (Visible) light, infrared (Mid-IR) light, near-infrared (Near-IR) light, far-infrared (Far-IR) light, sub-millimeter (Sub-mm) radiation, and/or terahertz (THz) radiation. 5. The method of claim 1 , wherein calculating the particle concentration uses the assumption of the optical particle counter and Mie theory or Rayleigh theory representing a scattering relationship of particles and electromagnetic waves. 6. The method of claim 1 , wherein the light path is generated by single pass spectroscopy, multi pass spectroscopy, and/or mixed spectroscopy of the single pass spectroscopy and the multi pass spectroscopy. 7. The method of claim 1 , wherein generating the light path includes generating the light path in an open path shape in which the light path is exposed to an ambient environment. 8. The method of claim 1 , wherein a distance between the first and second high reflection mirrors is within a range of 0.1 m to 1.5 m. 9. The method of claim 1 , wherein the light path is formed in a clean room environment, an atmospheric environment, and/or an indoor environment. 10. An optical measurement apparatus, comprising: a light generator configured to generate light; a light path cell having first and second high reflection mirrors that face each other to generate a light path by reflecting the light from the light generator; and a detector configured to simultaneously measure a particle concentration, representing solid and/or liquid particles suspended in a gas, and a gas concentration, representing the gas within which the solid and/or liquid particles are suspended, in the light path by using an assumption about characteristics of the solid and/or liquid particles for implementing an optical particle counter (OPC), wherein the detector expresses a light intensity as an extinction coefficient by using the Beer-Lambert Law, and measures the particle concentration and the gas concentration by using algebraic and statistical methodologies. 11. The optical measurement apparatus of claim 10 , wherein the assumption of the optical particle counter includes conditions that all particles are spherical, all particles have a density of 1 g/cm 3 , and all particles have optical refraction and absorption constants (m=n+ki), wherein m is a refractive index, n determines speed of light within a medium, k is an attenuation coefficient indicating attenuation of light, and i is an intensity of light. 12. The optical measurement apparatus of claim 10 , wherein the detector measures an optical characteristic of a particle and an optical characteristic of gas. 13. The optical measurement apparatus of claim 10 , wherein the detector separates the particle concentration and the gas concentration in the light path to extract the particle concentration. 14. The optical measurement apparatus of claim 10 , wherein the light generator generates the light of a preset wavelength according to a type of a particle to be measured, and wherein the light of the preset wavelength includes ultraviolet (UV) light, visible (Visible) light, infrared (Mid-IR) light, near-infrared (Near-IR) light, far-infrared (Far-IR) light, sub-millimeter (Sub-mm) radiation, and/or terahertz (THz) radiation. 15. The optical measurement apparatus of claim 10 , wherein the detector simultaneously measures the particle concentration and the gas concentration by using the assumption of the optical particle counter and Mie theory or Rayleigh theory representing a scattering relationship of particles and electromagnetic waves. 16. The optical measurement apparatus of claim 10 , wherein the light path has an open path shape exposed to an ambient environment. 17. The optical measurement apparatus of claim 10 , wherein a distance between the first and second high reflection mirrors is within a range of 0.1 m to 1.5 m. 18. A method of optical measurement, the method comprising: emitting light from a light generator; generating a light path by continuously reflecting the light emitted from the light generator between first and second high reflection mirrors that are open to an ambient environment; detecting an optical signal from an aerosol sample present within the light path, the aerosol sample including a gas and solid and/or liquid particles suspended within the gas; separating the optical signal into a particle signal representing the solid and/or liquid particles suspended in the gas and a gas signal representing the gas; calculating a particle concentration representing the solid and/or liquid particles suspended in the gas and optical characteristic of the particles from the particle signal by using particle concentration data measured by a particle counting device; and calculating a gas concentration representing the gas and optical characteristic of gas from the gas signal by using gas concentration data measured by a gas concentration measuring device, wherein the calculating of the particle concentration representing the solid and/or liquid particles suspe