Bragg grating based optical fiber sensor which is capable of measuring inflection point vector of chiral motion and manufacturing method thereof

What is claimed is: 1. A method for manufacturing an optical fiber sensor, the method comprising: forming three or more basic Bragg gratings in a core; and forming a plurality of sub Bragg grating between two continuous basic Bragg gratings in the core, wherein in the forming of the three or more basic Bragg gratings, the basic Bragg gratings are formed in the core with a long period that includes a plurality of sections having varying lengths, and wherein in the forming of the plurality of sub Bragg gratings, the sub Bragg gratings are formed with a short period of a uniform length, and the short period is shorter than the lengths of the plurality of sections. 2. The method for manufacturing an optical fiber sensor according to claim 1 , further comprising: before the forming of the three or more basic Bragg gratings, forming the core with a helical structure by rotating and injecting the core. 3. The method for manufacturing an optical fiber sensor according to claim 1 , wherein in the forming of the three or more basic Bragg gratings, the basic Bragg gratings are formed by irradiating ultraviolet onto the core. 4. The method for manufacturing an optical fiber sensor according to claim 1 , wherein in the forming of the plurality of sub Bragg gratings, the sub Bragg gratings are formed by irradiating pulse laser onto the core. 5. An optical fiber sensor, comprising: a core in which a Bragg grating is formed; and a cladding which surrounds the core, wherein the Bragg grating includes (i) three or more basic Bragg gratings and (ii) a plurality of sub Bragg gratings located between two continuous basic Bragg gratings, wherein the three or more basic Bragg gratings are formed in the core with a long period that includes a plurality of sections having varying lengths, and wherein the plurality of sub Bragg gratings are formed between the two continuous basic Bragg gratings with a short period of a uniform length, and the short period is shorter than the lengths of the plurality of sections. 6. The optical fiber sensor according to claim 5 , further comprising: a protective layer which surrounds the cladding, wherein the core is formed with a helical structure. 7. The optical fiber sensor according to claim 6 , wherein the protective layer is implemented by a woven material, and a helical angle of the helical structure and a braiding angle of the woven material are set to satisfy a predetermined condition range. 8. The optical fiber sensor according to claim 6 , wherein the core with the helical structure moves a wavelength of the Bragg grating using an elastic wave in accordance with the helical structure and accelerates a direction switching speed of the optical fiber sensor. 9. The optical fiber sensor according to claim 6 , wherein the core with the helical structure changes a critical angle of light by modifying an incident angle of light in accordance with the helical structure. 10. The optical fiber sensor according to claim 8 , wherein the basic Bragg grating does not affect the movement of the wavelength of the Bragg grating and forms a periodical pattern in a magnitude of the wavelength of the Bragg grating to provide a relative reference for space measurement. 11. The optical fiber sensor according to claim 5 , wherein the basic Bragg grating operates as a filter which passes regions other than a peak of a spectrum by a coupling phenomenon by interaction of a core mode and a cladding mode. 12. The optical fiber sensor according to claim 5 , wherein the long period includes a plurality of chirp sections having non-uniform lengths which linearly or non-linearly change in a light traveling direction. 13. The optical fiber sensor according to claim 5 , wherein a resonance of an optical signal is formed by a wavelength shift of the basic Bragg grating and a wavelength shift of the sub Bragg grating. 14. The optical fiber sensor according to claim 5 , further comprising: a plurality of elastic strings which surrounds the cladding. 15. The optical fiber sensor according to claim 5 , wherein the core and the cladding are formed on an elastic body, the elastic body includes a curve section and a linear section, and the sub Bragg grating is located in the linear section. 16. A vector measuring device comprising: an optical fiber sensor; a wavelength measuring unit which transmits an optical signal to the optical fiber sensor and receives an optical signal with a changed wavelength; and a vector processor which analyzes the optical signal with the changed wavelength to output a vector for a motion of a subject, wherein the optical fiber sensor includes: a core in which a Bragg grating is formed; and a cladding which surrounds the core, wherein the Bragg grating includes (i) three or more basic Bragg gratings and (ii) a plurality of sub Bragg gratings located between two continuous basic Bragg gratings, wherein the three or more basic Bragg gratings are formed in the core with a long period that includes a plurality of sections having varying lengths, and wherein the plurality of sub Bragg gratings are formed between the two continuous basic Bragg gratings with a short period of a uniform length, and the short period is shorter than the lengths of the plurality of sections.