Patent ID: 6330063
Filing Date: 2001-12-11
Classification: G01B,G01J,G01N,G02B

Abstract:
An optical coherence tomography apparatus for multi-dimensional imaging of a sample comprising:a plurality of parallel disposed interferometer modules for multi-channel investigation of the sample, each interferometer module comprisinga low coherence light source;a light exit opening for irradiating light into the sample;a detector;an optical coupler for joining a measuring light and a reference light in such a manner that both are incident on the detector at the same location to produce an interference signal such that light reflected at an LCI measuring depth beneath the interface of the sample is selectively detected;a reference reflector;a light source arm providing an optical path between the light source and the optical coupler and for irradiating measuring light into the sample;a sample arm providing an optical path between the optical coupler and the sample and for guiding reflected light from a reflection point inside the sample to the detector via the optical coupler;a detector arm between the optical coupler and the detector and for guiding reflected and reference light to the detector; and,a reference arm providing an optical path between the optical coupler and the reference reflector and for guiding reference light therebetween, said reference arm being commonly integrated with the optical coupler in an optical chip which includes a first light guide forming a first partial path of the reference arm and a second light guide forming a second partial path of the reference arm and a deflection reflector between the first partial path and the second partial path and formed at an end surface of the optical chip such that the reference light traveling from the optical coupler to the reference reflector and traveling from the reference reflector to the optical coupler is cross-coupled between the two light guides forming the first and second partial paths when traveling from the optical coupler to the reference reflector and when traveling from the reference reflector to the optical coupler;wherein an optical path length traveled by the reference light inside the optical chip along both partial paths of the reference arm between the optical coupler and the reference reflector is longer than the section of the sample arm between the optical coupler and the light exit opening but the optical light path length of the total measuring light path between the optical coupler and the reflection point inside the sample does not differ from the optical light path length of the reference arm by more than the coherence length of the low coherence light source.