OCT apparatus

An optical coherence tomography (OCT) apparatus according to an embodiment is configured to split light from a light source into measurement light and reference light, project the measurement light on an object, and detect interference light generated from the reference light and the measurement light returning from the object. The OCT apparatus includes a dispersion unit and an information generation unit. The dispersion unit is configured to relatively change a dispersion characteristic of a measurement optical path which is an optical path of the measurement light and a dispersion characteristic of a reference optical path which is an optical path of the reference light, according to an operation mode corresponding to a depth range. The information generation unit is configured to generate information on the object according to the operation mode, based on a detection result of the interference light.

CROSS-REFERENCE TO RELATED APPLICATION

This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2016-185220, filed Sep. 23, 2016, the entire contents of which are incorporated herein by reference.

BACKGROUND

In recent years, attention has been drawn to optical coherence tomography (OCT) which is used to form images representing the surface morphology and the internal morphology of an object using light beams emitted from a laser light source or the like. Since OCT does not have invasiveness to human body as X-ray CT (Computed Tomography) does, development of application of OCT in medical field and biology field is particularly expected. For example, in the field of ophthalmology, OCT apparatuses have been put to practical use for forming images of the fundus, the cornea, etc. and measuring the intraocular distance such as the axial length.

It is known that various artifacts are mixed in the image of an object obtained using OCT. In particular, the complex conjugate artifact is depicted in the image acquired with Fourier domain OCT. The complex conjugate artifact is the imaginary image that appears on the opposite side of the real image with respect to the zero delay position where the optical path length (OPL) of the measurement light applied to the object is equal to the optical path length of the reference light. For example, by forming a cross sectional image from the real image that appears on one side of the range (e.g., on the plus range) with respect to the zero delay position, it is possible to acquire a cross sectional image of the object with high image quality in a narrow depth range. Also, for example, by removing the complex conjugate artifact to form a cross sectional image, it is possible to acquire a cross sectional image of the object in the full range.

SUMMARY

An optical coherence tomography (OCT) apparatus according to an embodiment is configured to split light from a light source into measurement light and reference light, project the measurement light on an object, and detect interference light generated from the reference light and the measurement light returning from the object. The OCT apparatus includes a dispersion unit and an information generation unit. The dispersion unit is configured to relatively change a dispersion characteristic of a measurement optical path which is an optical path of the measurement light and a dispersion characteristic of a reference optical path which is an optical path of the reference light, according to an operation mode corresponding to a depth range. The information generation unit is configured to generate information on the object according to the operation mode, based on a detection result of the interference light.

DETAILED DESCRIPTION

Exemplary embodiments of the OCT apparatus according to the present invention will be described in detail with reference to the drawings. The contents of the documents cited in the present specification and arbitrary known techniques can be incorporated into the following embodiments.

The OCT apparatus according to the present embodiment has at least a function of performing OCT. The OCT apparatus is a measurement apparatus capable of acquiring information on an object by performing OCT on the object. Hereinafter, a case will be described where the OCT apparatus according to the present embodiment is an ophthalmic apparatus that acquires cross sectional images of a living eye by performing OCT on the living eye that is an object to be measured. However, embodiments are not limited thereto. For example, the OCT apparatus according to an embodiment may be an ophthalmic apparatus capable of measuring the intraocular distance of a living eye such as the axial length by performing OCT on the living eye.

The OCT apparatus according to the present embodiment is an ophthalmic apparatus that is a combination of a Fourier domain OCT apparatus and a fundus camera. The OCT apparatus has a function of performing swept source OCT, but embodiments are not limited to this. For example, the type of OCT is not limited to swept source OCT, and it may be the spectral domain OCT or the like. The swept source OCT is an OCT technique that splits light from a wavelength tunable type (i.e., a wavelength scanning type) light source into measurement light and reference light; superposes the measurement light returning from the object with the reference light to generate interference light; detects the interference light with a balanced photodiode or the like; and applies the Fourier transform etc. to the detection data acquired through the tuning of wavelengths and the scanning of the measurement light to form an image. On the other hand, spectral domain OCT is an OCT technique that splits light from a low coherence light source into measurement light and reference light; superposes the measurement light returning from the object with the reference light to generate interference light; detects the spectral distribution of the interference light with a spectrometer; and applies the Fourier transform etc. to the detected spectral distribution to form images.

The OCT apparatus according to the present embodiment may include a scanning laser ophthalmoscope (SLO), a slit lamp microscope, an anterior segment photographing camera, a surgical microscope, a photocoagulator, etc. in place of or in addition to the fundus camera. In the present specification, an image acquired using OCT is referred to as an OCT image. The optical path of the measurement light is denoted as a “measurement optical path”, and the optical path of the reference light is denoted as a “reference optical path”.

The ophthalmic apparatus1shown inFIG. 1includes the OCT apparatus according to the present embodiment. The ophthalmic apparatus1includes the fundus camera unit2, the OCT unit100, and the arithmetic and control unit200. The fundus camera unit2has substantially the same optical system as the conventional fundus camera. The OCT unit100is provided with an optical system for performing OCT. The arithmetic and control unit200is provided with one or more processors for performing various kinds of arithmetic processing, control processing, and the like.

In the present specification, the term “processor” is used to mean, for example, a circuity including a central processing unit (CPU), a graphics processing unit (GPU), an application specific integrated circuit (ASIC), a programmable logic device (e.g., a simple programmable logic device (SPLD), a complex programmable logic device (CPLD), or a field programmable gate array (FPGA)), or the like. The processor realizes the function according to the present embodiment, for example, by read out a computer program stored in a storage circuit or a storage device and executing the computer program.

The fundus camera unit2is provided with an optical system for acquiring two dimensional images (fundus images) rendering the surface morphology of the fundus Ef of the subject's eye E. Examples of the fundus images include observation images and photographed images. An observation image is, for example, a monochrome moving image formed at a predetermined frame rate using near-infrared light. A photographed image is, for example, a color image captured by flashing visible light, or a monochrome still image using near-infrared light or visible light as illumination light. The fundus camera unit2may be configured to be capable of acquiring other types of images such as fluorescein angiograms, indocyanine green angiograms, and autofluorescent angiograms.

The fundus camera unit2is provided with a jaw holder and a forehead rest for supporting the face of the subject. In addition, the fundus camera unit2is provided with the illumination optical system10and the photographing optical system30. The illumination optical system10projects illumination light onto the fundus Ef. The photographing optical system30guides the illumination light reflected from the fundus Ef to an imaging device (i.e., the CCD image sensors35or38). Each of the CCD image sensors35and38is sometimes simply referred to as a “CCD”. Further, the photographing optical system30guides measurement light coming from the OCT unit100to the subject's eye E, and guides the measurement light returning from the subject's eye E to the OCT unit100.

The observation light source11of the illumination optical system10includes, for example, a halogen lamp or a light emitting diode (LED). The light (observation illumination light) output from the observation light source11is reflected by the reflection mirror12having a concave reflective surface, passes through the condenser lens13, and becomes near-infrared light after passing through the visible cut filter14. Further, the observation illumination light is once converged near the photographing light source15, reflected by the mirror16, and passes through the relay lenses17and18, the diaphragm19, and the relay lens20. Then, the observation illumination light is reflected on the peripheral part (the surrounding area of the aperture part) of the aperture mirror21, penetrates the dichroic mirror46, and refracted by the objective lens22, thereby illuminating the fundus Ef.

The observation illumination light reflected from the fundus Ef is refracted by the objective lens22, penetrates the dichroic mirror46, passes through the aperture part formed in the center area of the aperture mirror21, passes through the dichroic mirror55, travels through the photography focusing lens31, and is reflected by the mirror32. Further, the fundus reflection light passes through the half mirror33A, is reflected by the dichroic mirror33, and forms an image on the light receiving surface of the CCD image sensor35by the condenser lens34. The CCD image sensor35detects the fundus reflection light at a predetermined frame rate, for example. An image (observation image) based on the fundus reflection light detected by the CCD image sensor35is displayed on the display device3. Note that when the focus of the photographing optical system30is adjusted to the anterior segment of the subject's eye E, an observation image of the anterior segment of the subject's eye E is acquired and displayed.

The photographing light source15is formed of, for example, a xenon lamp or an LED. The light (photographing illumination light) output from the photographing light source15is guided to the fundus Ef along the same route as that of the observation illumination light. The photographing illumination light reflected from the fundus Ef is guided to the dichroic mirror33along the same route as that of the observation illumination light, passes through the dichroic mirror33, is reflected by the mirror36, and forms an image on the light receiving surface of the CCD image sensor38by the condenser lens37. The display device3displays an image (photographed image) based on the fundus reflection light detected by the CCD image sensor38. Note that the same device or different devices may be used for the display device3for displaying observation images and the display device3for displaying photographed images. Besides, when similar photography is performed by illuminating the subject's eye E with infrared light, an infrared photographed image is displayed.

The liquid crystal display (LCD)39displays a fixation target and a visual target used for visual acuity measurement. The fixation target is a visual target for fixating the subject's eye E, and is used when performing fundus photography and OCT measurement.

Part of the light output from the LCD39is reflected by the half mirror33A, reflected by the mirror32, travels through the photography focusing lens31and the dichroic mirror55, and passes through the aperture part of the aperture mirror21. The light passed through the aperture part of the aperture mirror21penetrates the dichroic mirror46, and is refracted by the objective lens22, thereby being projected onto the fundus Ef. By changing the display position of the fixation target on the screen of the LCD39, the fixation position of the subject's eye E can be changed.

In addition, as with a conventional fundus camera, the fundus camera unit2is provided with the alignment optical system50and the focus optical system60. The alignment optical system50generates an indicator (referred to as an alignment indicator) for the position adjustment (i.e., the alignment) of the optical system with respect to the subject's eye E. The focus optical system60generates an indicator (referred to as a split indicator) for adjusting the focus of the photographing optical system30with respect to the subject's eye E.

The light output from an LED51of the alignment optical system50(i.e., alignment light) travels through the diaphragms52and53and the relay lens54, is reflected by the dichroic mirror55, and passes through the aperture part of the aperture mirror21. The alignment light passed through the aperture part of the aperture mirror21penetrates the dichroic mirror46, and is projected onto the cornea of the subject's eye E by the objective lens22.

The alignment light reflected from the cornea travels through the objective lens22, the dichroic mirror46and the above-mentioned aperture part. Part of the cornea reflection light penetrates the dichroic mirror55and passes through the photography focusing lens31. The cornea reflection light passed through the photography focusing lens31is reflected by the mirror32, penetrates the half mirror33A, is reflected by the dichroic mirror33, and is projected onto the light receiving surface of the CCD image sensor35by the condenser lens34. The received image (i.e., alignment indicator image) captured by the CCD image sensor35is displayed on the display device3together with the observation image. The user conducts an alignment operation in the same manner as performed on a conventional fundus camera. Instead, alignment may be performed in such a way that the arithmetic and control unit200analyzes the position of the alignment indicator image and moves the optical system (automatic alignment).

The focus optical system60is movable along the optical path of the illumination optical system10in conjunction with the movement of the photography focusing lens31along the optical path of the photographing optical system30. The reflection rod67of the focus optical system60can be inserted and removed into and from the illumination optical path.

To conduct focus adjustment, the reflective surface of the reflection rod67is arranged in a slanted position on the illumination optical path. The light output from the LED61of the focus optical system60(i.e., focus light) passes through the relay lens62, is split into two light beams by the split indicator plate63, passes through the two-hole diaphragm64. The focus light passed through the two-hole diaphragm64is reflected by the mirror65, is converged on the reflective surface of the reflection rod67by the condenser lens66, and is reflected by the reflective surface. Further, the focus light travels through the relay lens20, is reflected by the aperture mirror21, penetrates the dichroic mirror46, and is refracted by the objective lens22, thereby being projected onto the fundus Ef.

The focus light reflected from the fundus is guided along the same route as the alignment light reflected from the cornea and is detected by the CCD image sensor35. The received image (i.e., split indicator image) captured by the CCD image sensor35is displayed on the display device3together with the observation image. As in the conventional case, the arithmetic and control unit200can analyze the position of the split indicator image, and move the photography focusing lens31and the focus optical system60for the focus adjustment (automatic focusing). Instead, the user may manually perform the focus adjustment while visually checking the split indicator image.

The reflection rod67is inserted at a position on the illumination optical path substantially optically conjugate with the fundus Ef of the subject's eye E. The position of the reflective surface of the reflection rod67inserted in the optical path of the illumination optical system10is a position substantially optically conjugate with the split indicator plate63. As described above, the split indicator light beam is split into two beams by the action of the two-hole diaphragm64and the like. When the fundus Ef of the subject's eye E and the reflective surface of the reflection rod67are not conjugate, two split indicator images acquired by the CCD image sensor35are displayed on the display device3in such a way that the split indicator images are separated in the right-and-left direction, for example. When the fundus Ef of the subject's eye E and the reflective surface of the reflection rod67are substantially optically conjugate with each other, the two split indicator images are displayed on the display device3in such a way that the positions of the split indicator images acquired by the CCD image sensor35coincide with each other in the vertical direction, for example. The focus optical system60is moved along the optical path of the illumination optical system10in conjunction with the movement of the photography focusing lens31so that the fundus Ef and the split indicator plate63are always optically conjugate with each other. When the fundus Ef and the split indicator plate63are not conjugate, the split indicator image is separated into two. Thus, the position of the photography focusing lens31is obtained by moving the focus optical system60so that the two split indicator images coincide with each other in the vertical direction. In the present embodiment, the case where two split indicator images are acquired has been described, but the number of split indicator images may be three or more.

The dichroic mirror46branches the optical path for OCT from the optical path for fundus photography. The dichroic mirror46reflects light of wavelengths used in OCT, and transmits light for fundus photography. The optical path for OCT is provided with, in order from the OCT unit100side, the collimator lens unit40, the optical path length (OPL) changing unit41, the optical scanner42, the OCT focusing lens43, the mirror44, and the relay lens45.

The collimator lens unit40includes a collimator lens. The collimator lens unit40is optically connected to the OCT unit100with an optical fiber. A collimator lens in the collimator lens unit40is disposed at a position facing the emitting end of the optical fiber. The collimator lens unit40converts the measurement light LS (described later) emitted from the emitting end of the optical fiber into a parallel light beam and converges the returning light of the measurement light LS from the subject's eye E to the emitting end of the optical fiber.

The optical path length changing unit41is movable in directions indicated by the arrow inFIG. 1, thereby changing the length of the optical path for OCT measurement. The change in the optical path length is used for correcting the optical path length according to the axial length of the subject's eye E, for adjusting the interference state, and the like. The optical path length changing unit41includes, for example, a corner cube and a mechanism for moving the corner cube.

The optical scanner42is disposed at a position optically conjugate with the pupil of the subject's eye E. The optical scanner42changes the traveling direction of the light (measurement light LS) traveling along the OCT optical path. With this, the subject's eye E can be scanned with the measurement light LS. The optical scanner42includes, for example, a galvano mirror that deflects the measurement light LS in the x direction, a galvano mirror that deflects the measurement light LS in the y direction, and a mechanism(s) that independently drives the galvano mirrors. With this, it is possible to scan the measurement light LS in an arbitrary direction in the xy plane.

The dispersion member80is inserted into and removed from the measurement optical path between the collimator lens unit40and the optical scanner42. The dispersion member80gives a predetermined dispersion amount to the measurement optical path. The dispersion amount increases the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path described later. Specifically, the dispersion amount may be equal to or larger than 30n radians when the optical path length difference caused by chromatic dispersion between the reference optical path and the measurement optical path is converted into a phase difference. For the dispersion member80as such, a glass material of a kind and a thickness corresponding to the dispersion amount is used. In the present embodiment, the dispersion member80is inserted into and removed from the measurement optical path in accordance with the operation mode corresponding to the depth range of the ophthalmic apparatus1.

An example of the configuration of the OCT unit100is shown inFIG. 2. The OCT unit100includes an optical system for acquiring OCT images of the subject's eye E. The optical system includes an interference optical system (i.e., interferometer) that splits the light from a wavelength tunable type (i.e., a wavelength scanning type) light source into measurement light and reference light, makes the measurement light returning from the subject's eye E and the reference light having traveled through the reference optical path interfere with each other to generate interference light, and detects the interference light. The detection result of the interference light obtained by the interference optical system (i.e., the detection signal) is an interference signal indicating the spectrum of the interference light, and is sent to the arithmetic and control unit200.

Like swept source OCT apparatuses commonly used, the light source unit101includes a wavelength tunable type (i.e., a wavelength scanning type) light source capable of sweeping (scanning) the wavelengths of emitted light. The wavelength tunable type light source includes a laser light source that includes a resonator. The light source unit101temporally changes the output wavelengths within the near infrared wavelength bands that cannot be visually recognized with human eyes.

The light L0output from the light source unit101is guided to the polarization controller103through the optical fiber102and the polarization state thereof is adjusted. The polarization controller103, for example, applies external stress to the looped optical fiber102to thereby adjust the polarization state of the light L0guided through the optical fiber102.

The light L0whose polarization state has been adjusted by the polarization controller103is guided to the fiber coupler105through the optical fiber104and is split into the measurement light LS and the reference light LR.

The reference light LR is guided to the collimator111through the optical fiber110and becomes a parallel light beam. The reference light LR, which has become a parallel light beam, is guided to the corner cube114. The corner cube114changes the traveling direction of the reference light LR that has been made into the parallel light beam by the collimator111in the opposite direction. The optical path of the reference light LR incident on the corner cube114and the optical path of the reference light LR emitted from the corner cube114are parallel. Further, the corner cube114is movable in a direction along the incident light path and the emitting light path of the reference light LR. Through such movement, the length of the optical path of the reference light LR is varied.

The configuration shown inFIG. 1andFIG. 2includes both the optical path length changing unit41that changes the length of the optical path of the measurement light LS (i.e., measurement optical path or measurement arm) and the corner cube114that changes the length of the optical path of the reference light LR (i.e., reference optical path or reference arm). However, an OCT apparatus of another embodiment may include the corner cube114only. An OCT apparatus of yet another embodiment may be configured to change the difference between the measurement optical path length and the reference optical path length using another kind of optical member.

The reference light LR that has traveled through the corner cube114is converted from the parallel light beam to the convergent light beam by the collimator116and enters the optical fiber117. The dispersion member150is inserted into and removed from at least one of the reference optical path between the collimator111and the corner cube114and the reference optical path between the collimator116and the corner cube114. The dispersion member150gives a predetermined dispersion amount to the reference optical path. The dispersion amount, for example, compensates for the difference between the dispersion characteristic of the measurement optical path in which the dispersion member80is not disposed and the dispersion characteristic of the reference optical path. For the dispersion member150as such, a glass material of a kind and a thickness corresponding to the dispersion amount is used. In the present embodiment, the dispersion member150is inserted into and removed from the reference optical path in accordance with the operation mode of the ophthalmic apparatus1.

An optical path length correction member may be disposed in at least one of the reference optical path between the collimator111and the corner cube114and the reference optical path between the collimator116and the corner cube114. The optical path length correction member functions as a delaying means for matching the optical path length (i.e., optical distance) of the reference light LR with the optical path length of the measurement light LS.

The reference light LR that has entered the optical fiber117is guided to the polarization controller118. With the polarization controller118, the polarization state of the reference light LR is adjusted. The polarization controller118has the same configuration as, for example, the polarization controller103. The reference light LR whose polarization state has been adjusted by the polarization controller118is guided to the attenuator120through the optical fiber119and the light amount is adjusted by the attenuator120under the control of the arithmetic and control unit200. The reference light LR whose light amount is adjusted by the attenuator120is guided to the fiber coupler122through the optical fiber121.

Meanwhile, the measurement light LS generated by the fiber coupler105is guided through the optical fiber127, and is made into the parallel light beam by the collimator lens unit40. When the dispersion member80is not disposed in the measurement optical path, the measurement light LS made into the parallel light beam is guided to the dichroic mirror46via the optical path length changing unit41, the optical scanner42, the OCT focusing lens43, the mirror44, and the relay lens45. When the dispersion member80is disposed in the measurement optical path, the measurement light LS made into the parallel light beam is guided to the dichroic mirror46via the dispersion member80, the optical path length changing unit41, the optical scanner42, the OCT focusing lens43, the mirror44, and the relay lens45. The measurement light LS guided to the dichroic mirror46is reflected by the dichroic mirror46, refracted by the objective lens22, and projected onto the subject's eye E. The measurement light LS is scattered (and reflected) at various depth positions of the subject's eye E. The returning light of the measurement light LS including such backscattered light advances through the same path as the outward path in the opposite direction and is led to the fiber coupler105, and then reaches the fiber coupler122through the optical fiber128.

The fiber coupler122superposes the measurement light LS incident through the optical fiber128and the reference light LR incident through the optical fiber121with each other to generate interference light. The fiber coupler122generates a pair of interference light LC by splitting the interference light generated from the measurement light LS and the reference light LR at a predetermined splitting ratio (for example, 1:1). The pair of the interference light LC emitted from the fiber coupler122is guided to a detector125through optical fibers123and124, respectively.

The detector125is, for example, a balanced photodiode that includes a pair of photodetectors for respectively detecting the pair of the interference light LC and outputs the difference between the pair of detection results obtained by the pair of photodetectors. The detector125sends the detection result (i.e., interference signal) to the data acquisition system (DAQ)130. The clock KC is supplied from the light source unit101to the DAQ130. The clock KC is generated in the light source unit101in synchronization with the output timing of each wavelength sweeping (i.e., wavelength scanning) within a predetermined wavelength range performed by the wavelength tunable type light source. For example, the light source unit101optically delays one of the two pieces of branched light obtained by branching the light L0of each output wavelength, and then generates the clock KC based on the result of the detection of the combined light of the two pieces of branched light. The DAQ130performs the sampling of the detection result obtained by the detector125based on the clock KC. The DAQ130sends the result of the sampling of the detection result obtained by the detector125to the arithmetic and control unit200. For example, the arithmetic and control unit200performs the Fourier transform etc. on the spectral distribution based on the detection result obtained by the detector125for each series of wavelength scanning (i.e., for each A line). With this, the reflection intensity profile for each A line is formed. In addition, the arithmetic and control unit200forms image data by applying imaging processing to the reflection intensity profiles of the respective A lines.

[Arithmetic and Control Unit]

The configuration of the arithmetic and control unit200will be described. The arithmetic and control unit200analyzes the interference signals input from the detector125to form an OCT image of the subject's eye E. The arithmetic processing for forming an OCT image corresponding to a depth range narrower than the full range is executed in the same manner as the conventional swept source OCT.

In addition, the arithmetic and control unit200controls each part of the fundus camera unit2, the display device3, and the OCT unit100. For example, the arithmetic and control unit200controls the display device3to display the OCT image of the subject's eye E.

Like conventional computers, the arithmetic and control unit200includes a microprocessor, a random access memory (RAM), a read only memory (ROM), a hard disk drive, a communication interface, and the like. A storage device such as the hard disk drive stores a computer program for controlling the ophthalmic apparatus1. The arithmetic and control unit200may include various kinds of circuitry such as a circuit board for forming OCT images. In addition, the arithmetic and control unit200may include an operation device (or an input device) such as a keyboard and a mouse, and a display device such as an LCD.

The configuration of the control system of the ophthalmic apparatus1will be described with reference toFIG. 3. InFIG. 3, some components of the ophthalmic apparatus1are omitted, and the components particularly necessary for describing the present embodiment are selectively shown.

The arithmetic and control unit200includes the controller210, the image forming unit220, and the data processor230. The controller210includes, for example, a microprocessor, a RAM, a ROM, a hard disk drive, a communication interface, and the like. The controller210is provided with the main controller211and the storage unit212.

The main controller211performs various kinds of controls mentioned above. In particular, as shown inFIG. 3, the main controller211controls components of the fundus camera unit2such as the movement mechanisms31A and80A, the CCD image sensors35and38, the LCD39, the optical path length changing unit41, and the optical scanner42. In addition, the main controller211controls components of the OCT unit100such as the light source unit101, the movement mechanisms114A and150A of, the detector125, and the DAQ130.

The ophthalmic apparatus1according to the present embodiment forms an OCT image corresponding to any of two or more operation modes corresponding to different depth ranges. The selection (or designation) of the operation mode may be performed by the main controller211, or may be performed by the user operating the operation unit242described later. When the operation mode is selected by the main controller211, the same operation mode as the previous operation may be selected, or the operation mode may be selected according to the object or the purpose of diagnosis.

In the present embodiment, operation mode options include a standard OCT mode and a full range OCT mode. The standard OCT mode is an operation mode for forming an OCT image with a high S/N ratio in a narrow depth range by using an interference signal appearing on one side of the range (i.e., on the plus range or the minus range) with respect to the zero delay position. The full range OCT mode is an operation mode for forming a full range OCT image by using both an interference signal on the plus range side and an interference signal on the minus range side. In the full range OCT mode, it is possible to acquire an OCT image that does not cause aliasing (that is, an OCT image that includes no mirror image), such as when acquiring a wide-angle cross sectional image of the subject's eye E or when the subject's eye E is of high myopia. In the standard OCT mode, for example, it is possible to acquire an OCT image with high image quality although the depth range in the standard mode is narrower than that in the full range. The standard OCT mode may also be selected when acquiring an OCT image in the vicinity of the zero delay position where the noise is superimposed in the full range.

The movement mechanism31A moves the photography focusing lens31along the optical axis of the photographing optical system30. The movement mechanism31A is provided with a holding member that holds the photography focusing lens31, an actuator that generates a driving force for moving the holding member, and a transmission mechanism that transmits the driving force from the actuator to the holding member. The actuator may be a pulse motor. The transmission mechanism may include a combination of gears, and a rack and pinion. As a result, the movement mechanism31A controlled by the controller210moves the photography focusing lens31, thereby the focus position of the photographing optical system30is changed. Note that the movement mechanism31A may be configured to move the photography focusing lens31along the optical axis of the photographing optical system30in accordance with a manual operation or the user's operation on the operation unit242.

Incidentally, the main controller211may be configured to control an optical system driver (not illustrated) to move the optical system of the ophthalmic apparatus1in the three dimensional manner. This control is used in alignment and tracking. Here, tracking is an operation of moving the optical system of the ophthalmic apparatus1according to the movement of the subject's eye E. To perform tracking, alignment and focusing are performed in advance. Tracking is a function of maintaining a suitable positional relationship in which alignment and focusing are matched, which is realized by moving the optical system of the apparatus in real time according to the position and orientation of the subject's eye E based on the moving image obtained by performing movie shoot of the subject's eye E.

The movement mechanism80A inserts and removes the dispersion member80into and from the measurement optical path. The movement mechanism80A is provided with a holding member that holds the dispersion member80, an actuator that generates a driving force for moving the holding member, and a transmission mechanism that transmits the driving force from the actuator to the holding member. As a result, the movement mechanism80A controlled by the controller210inserts and removes the dispersion member80into and from the measurement optical path. With this, the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path is changed. Note that the movement mechanism80A may be configured to insert and remove the dispersion member80into and from the measurement optical path according to a manual operation or the user's operation on the operation unit242.

The movement mechanism114A moves the corner cube114provided in the reference optical path. The movement mechanism114A is provided with a holding member that holds the corner cube114, an actuator that generates a driving force for moving the holding member, and a transmission mechanism that transmits the driving force from the actuator to the holding member. As a result, the length of the reference optical path is changed. Note that the movement mechanism114A may be configured to move the corner cube114along the reference optical path according to a manual operation or the user's operation on the operation unit242.

The movement mechanism150A inserts and removes the dispersion member150into and from the reference optical path. The movement mechanism150A is provided with a holding member that holds the dispersion member150, an actuator that generates a driving force for moving the holding member, and a transmission mechanism that transmits the driving force from the actuator to the holding member. As a result, the movement mechanism150A controlled by the controller210inserts and removes the dispersion member150into and from the reference optical path. With this, the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path is changed. Note that the movement mechanism150A may insert and remove the dispersion member150into and from the reference optical path according to a manual operation or the user's operation on the operation unit242.

The storage unit212stores various kinds of data. Examples of the data stored in the storage unit212include operation mode information of the ophthalmic apparatus1, image data of an OCT image, image data of a fundus image, and subject's eye information. The subject's eye information includes information related to a subject such as patient ID and name, information related to a subject's eye such as identification information of left eye/right eye, and the like. In addition, the storage unit212stores various kinds of programs and various kinds of data to run the ophthalmic apparatus1.

The image forming unit220forms image data of a cross sectional image of the fundus Ef based on the interference signals from the detector125(i.e., from the DAQ130) according to the operation mode. That is, the image forming unit220forms the image data of the subject's eye E based on the detection result of the interference light LC obtained by the interference optical system according to the operation mode. The image formation process includes noise removal (noise reduction), filtering, fast Fourier transform (FFT), and the like. The image data acquired in this manner is a data set including a group of image data formed by imaging the reflection intensity profiles of a plurality of A lines. Here, the plurality of A lines corresponds to the paths of the respective pieces of the measurement light LS in the eye E.

In order to improve the image quality, it is possible to repeatedly perform scan with the same pattern a plurality of times to collect a plurality of data sets, and to compose (e.g., to perform addition and average) the plurality of data sets.

Further, the image forming unit220forms an image in which two or more split indicator images are depicted from the image signal detected by the CCD35based on the returning light of two or more split indicators from the eye E that has passed through the photography focusing lens31. Note that the main controller211may be configured to perform the formation of the image in which the two or more split indicator images are depicted.

The image forming unit220includes, for example, the circuitry described above. Note that “image data” and an “image” based on the image data may not be distinguished from each other in the present specification. In addition, a site of the subject's eye E and an image of the site may not be distinguished from each other.

The data processor230performs various kinds of data processing (e.g., image processing) and various kinds of analysis on an image formed by the image forming unit220. For example, the data processor230performs various correction processes such as brightness correction and dispersion correction of images. The data processor230performs various kinds of image processing and analysis on images captured by the fundus camera unit2(e.g., fundus images, anterior segment images, etc.).

The data processor230can form volume data (voxel data) of the subject's eye E by performing known image processing such as interpolation processing for interpolating pixels between cross sectional images. In the case of displaying an image based on the volume data, the data processor230performs a rendering process on the volume data so as to form a pseudo three dimensional image viewed from a specific line-of-sight direction.

The data processor230can perform registration (i.e., position matching) between a fundus image and an OCT image. When the fundus image and the OCT image are obtained in parallel, the registration between the fundus image and the OCT image, which have been (almost) simultaneously obtained, can be performed using the optical axis of the photographing optical system30as a reference. Such registration can be achieved since the optical system for the fundus image and that for the OCT image are coaxial. Besides, regardless of the timing of obtaining the fundus image and that of the OCT image, the registration between a fundus image and an OCT image can be achieved by performing the registration between the fundus image with a front image formed by projecting at least part of the image area in the OCT image corresponding to the fundus Ef onto the xy plane. Such a registration technique can also be employed when the optical system for acquiring fundus images and the optical system for OCT are not coaxial. Further, when the optical system for acquiring fundus images and the optical system for OCT are not coaxial, if the relative positional relationship between these optical systems is known or can be detected, the registration can be performed with referring to the relative positional relationship in a similar manner to the case in which the optical systems are coaxial.

The data processor230that functions as above includes, for example, a microprocessor, a RAM, a ROM, a hard disk drive, a circuit board, and the like. The storage device such as the hard disk drive stores, in advance, a computer program for causing the microprocessor to execute the functions described above.

The user interface240includes the display unit241and the operation unit242. The display unit241includes the aforementioned display device of the arithmetic and control unit200and the display device3. The operation unit242includes the aforementioned operation device of the arithmetic and control unit200. The operation unit242may include various kinds of buttons and keys provided on the housing of the ophthalmic apparatus1, or provided outside the ophthalmic apparatus1. Further, the display unit241may include various kinds of display devices, such as a touch panel placed on the housing of the fundus camera unit2.

Note that the display unit241and the operation unit242need not necessarily be formed as separate devices. For example, a device like a touch panel, which has a display function integrated with an operation function, can be used. In such a case, the operation unit242includes the touch panel and a computer program. The content of an operation performed using the operation unit242is fed to the controller210as an electrical signal. Moreover, operations and inputs of information may be performed using a graphical user interface (GUI) displayed on the display unit241and the operation unit242.

FIG. 4shows a diagram405describing the operation of the ophthalmic apparatus1according to the present embodiment.FIG. 4schematically shows the arrangement states of the dispersion members80and150when the operation mode is set to the full range OCT mode. InFIG. 4, parts similar to those inFIG. 1toFIG. 3are denoted by the same reference symbols, and description thereof is omitted as appropriate.

When the operation mode is set to the standard OCT mode, the controller210(e.g., the main controller211) controls the movement mechanism80A to remove the dispersion member80from the measurement optical path, and controls the movement mechanism150A to dispose the dispersion member150in the reference optical path. With this, the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path is compensated. The measurement light LS generated based on the light L0emitted from the light source unit101is projected onto the eye E as described above. The detector125receives the interference light LC, and the interference signal obtained by the detector125is sampled by the DAQ130. The image forming unit220performs known numerical dispersion compensation processing on the sampled interference signal (i.e., spectra). Subsequently, the image forming unit220performs a known FFT process on the signal to which the dispersion compensation processing has been performed and assigns brightness values to the amplitude components generated based on the plus range side signal (or the minus range side signal) with respect to the zero delay position to form an OCT image. The image forming unit220may be configured to perform apodization processing using a window function such as known Hanning window or Gaussian window on the interference signal obtained by the detector125and perform the aforementioned dispersion compensation processing on the signal to which the apodization processing has been performed. Such processing is disclosed in, for example, Japanese Unexamined Patent Application Publication No. 2015-70919.

In general, if there is a difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path, the point spread function (hereinafter referred to as PSF) determined from the interference signal becomes dull and the S/N ratio decreases, which results in degradation of the image quality of the OCT image. In the present embodiment, the dispersion member150is disposed in the reference optical path so as to compensate for the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path. Accordingly, when generating an OCT image in a depth range narrower than the full range, it is possible to detect the interference signal with a high S/N ratio and acquire an OCT image with high image quality.

FIG. 5AtoFIG. 5Cshow diagrams505,510, and515, respectively, describing the operation of the ophthalmic apparatus1according to the present embodiment.FIG. 5AtoFIG. 5Cshow examples of the PSF determined from the interference signal obtained by the detector125in the full range OCT mode.

When the operation mode is set to the full range OCT mode, the main controller211controls the movement mechanism80A to dispose the dispersion member80in the measurement optical path, and controls the movement mechanism150A to remove the dispersion member150from the reference optical path. With this, the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path becomes large. In this case, the waveform of the PSF of the interference signal obtained by the detector125(e.g., the waveform H1shown inFIG. 5A) is duller than the waveform of the PSF of the interference signal detected in the standard OCT mode (e.g., the waveform H0shown inFIG. 5A). The image forming unit220performs known dispersion compensation processing on the interference signal obtained by the detector125so that the waveform of the PSF of the interference signal on the minus range side becomes steep (e.g., the waveform H2shown inFIG. 5B), for example. Subsequently, the image forming unit220detects and removes the interference signal on the minus range side where the waveform has become steep, and performs the above-described dispersion compensation processing in which the sign is inverted on the remaining interference signal on the plus range side (e.g., the waveform H3shown inFIG. 5C). Next, the image forming unit220performs a known FFT process on the signal to which the dispersion compensation processing has been applied, and assigns brightness values to the generated amplitude components to form a full range OCT image.

In order to improve the image quality of the OCT image, the improvement of the S/N ratio of the interference signal is necessary. In order to improve the S/N ratio, any of the following is necessary: increasing the light amount of the measurement light LS incident on the subject's eye E; improving the light reception efficiency of the interference light LC with the detector125; and suppressing the light amount loss of the OCT optical system. However, considering the safety of the subject, the amount of light incident on the subject's eye E is limited, and the improvement in the light reception efficiency of the interference light LC with the detector125is also limited. Therefore, it can be thought that the suppression of the light amount loss of the OCT optical system is most effective for improving the image quality of the OCT image. In the present embodiment, when an OCT image is formed in the full range, the dispersion amount of the dispersion member80disposed in the measurement optical path as described above is set to be equal to or larger than 30n radians when the optical path length difference caused by the chromatic dispersion between the reference optical path and the measurement optical path is converted into the phase difference. When the dispersion amount of the dispersion member80is small, for example, as shown inFIG. 6in OCT image605describing an operation of the OCT apparatus according to the embodiment, a mirror image is depicted in the formed OCT image605. On the other hand, according to the present embodiment, it is easy to detect the interference signal appearing on one range side with respect to the zero delay position while suppressing the light amount loss of the measurement light. Thus, an OCT image705of a high image quality in the full range can be acquired as shown inFIG. 7.

The dispersion member80, the movement mechanism80A, the dispersion member150, and the movement mechanism150A are an example of the “dispersion unit” which relatively changes the dispersion characteristics of the measurement optical path and the dispersion characteristics of the reference optical path according to the operation mode in the present embodiment. The dispersion member80is an example of the “first dispersion member” according to the present embodiment. The movement mechanism80A is an example of the “first movement mechanism” according to the present embodiment. The dispersion member150is an example of the “second dispersion member” according to the present embodiment. The movement mechanism150A is an example of the “second movement mechanism” according to the present embodiment. The standard OCT mode is an example of the “first operation mode” according to the present embodiment. The full range OCT mode is an example of the “second operation mode” according to the present embodiment. The arithmetic and control unit200is an example of the “information generation unit” that generates information on the object according to the operation mode, based on the detection result of the interference light in the present embodiment. The operation unit242is an example of the “selection unit” according to the present embodiment.

OPERATION EXAMPLES

The operation of the ophthalmic apparatus1according to the present embodiment will be described.

FIG. 8andFIG. 9show an example of the operation of the ophthalmic apparatus1according to the present embodiment.FIG. 8andFIG. 9show a flow chart800of an operation example in the case of acquiring an OCT image of the subject's eye E.

(Step805Also Referred to Herein as S1)

First, the main controller211determines whether or not the operation mode of the ophthalmic apparatus1is set to the standard OCT mode. For example, the storage unit212stores operation mode information indicating setting contents of operation modes of the ophthalmic apparatus1. By referring to the operation mode information stored in the storage unit212, the main controller211can determine whether or not the operation mode of the ophthalmic apparatus1is set to the standard OCT mode.

When it is determined that the operation mode is set to the standard OCT mode (S1: Y), the operation of the ophthalmic apparatus1proceeds to the step S2. When it is determined that the operation mode is not set to the standard OCT mode (S1: N), the operation of the ophthalmic apparatus1proceeds to the step S4.

(Step810also referred to herein as S2)

When it is determined in the step S1that the operation mode is set to the standard OCT mode (S1: Y), the main controller211determines whether or not the dispersion members80and150are disposed for the standard OCT imaging. The main controller211may be configured to determine whether or not the dispersion members80and150are disposed for the standard OCT imaging by referring to the control contents for the movement mechanisms80A and150A. In another example, a sensor for detecting the insertion and removal states of the dispersion members80and150with respect to the optical paths may be provided, and the main controller211may be configured to determine whether or not the dispersion members80and150are disposed for the standard OCT imaging based on the detection signal from the sensor.

When it is determined that the dispersion members80and150are disposed for the standard OCT imaging (S2: Y), the operation of the ophthalmic apparatus1proceeds to the step S6. When it is determined that the dispersion members80and150are not disposed for the standard OCT imaging (S2: N), the operation of the ophthalmic apparatus1proceeds to the step S3.

(Step815Also Referred to Herein as S3)

When it is determined in the step S2that the dispersion members80and150are not disposed for the standard OCT imaging (S2: N), the main controller211controls the movement mechanism80A to remove the dispersion member80from the measurement optical path and controls the movement mechanism150A to dispose the dispersion member150in the reference optical path. Then, the operation of the ophthalmic apparatus1proceeds to the step S6.

(Step820Also Referred to Herein as S4)

When it is determined in the step S1that the operation mode is not set to the standard OCT mode (S1: N), the main controller211determines that the operation mode is set to the full range OCT mode. The main controller211then determines whether or not the dispersion members80and150are disposed for the full range OCT imaging. By referring to the control contents for the movement mechanisms80A and150A, the main controller211can judge whether or not the dispersion members80and150are disposed for the full range OCT imaging. In another example, as described above, a sensor for detecting the insertion and removal state of the dispersion members80and150with respect to the optical path may be provided, and the main controller211may be configured to determine whether or not the dispersion members80and150are disposed for the full range OCT imaging based on the detection signal from the sensor.

When it is determined that the dispersion members80and150are disposed for the full range OCT imaging (S4: Y), the operation of the ophthalmic apparatus1moves to the steps S6. When it is determined that the dispersion members80and150are not disposed for the full range OCT imaging (S4: N), the operation of the ophthalmic apparatus1proceeds to the step S5.

(Step825Also Referred to Herein as S5)

When it is determined in the step S4that the dispersion members80and150are not disposed for the full range OCT imaging (S4: N), the main controller211controls the movement mechanism80A to dispose the dispersion member80in the measurement optical path, and controls the movement mechanism150A to remove the dispersion member150from the reference optical path. The operation of the ophthalmic apparatus1proceeds to the step S6.

(Step830Also Referred to Herein as S6)

The main controller211images the anterior segment of the subject's eye E using the photographing optical system30to acquire an anterior segment image.

(Step835Also Referred to Herein as S7)

The main controller211controls the optical system driver described above based on the anterior segment image acquired in the step S6to move the optical system in the three-dimensional fashion, thereby performing the position matching of the optical system with respect to the subject's eye E in the x direction, the y direction, and the z direction orthogonal to both the x direction and the y direction.

(Step840Also Referred to Herein as S8)

The main controller211moves the optical scanner42to a predetermined initial position.

(Step845Also Referred to Herein as S9)

The main controller211turns on the light source unit101and controls the optical scanner42to start scanning the fundus Ef of the subject's eye E with the measurement light LS based on the light L0emitted from the light source unit101. As described above, the image forming unit220forms an OCT image of the fundus Ef based on the detection result of the interference light obtained by the detector1125according to the operation mode.

(Step850Also Referred to Herein as S10)

The main controller211performs alignment in the focus direction of the retina based on the anterior segment image obtained by the photographing optical system30. With this, it becomes possible to finely adjust the position of the optical system provided in the OCT unit100in the optical axis direction.

(Step855Also Referred to Herein as S11)

Based on the detection signal of the interference light obtained by the OCT optical system, the main controller211changes the focus position of the optical system of the OCT unit100. The main controller211changes the focus position of the optical system, for example, by moving the OCT focusing lens43in the optical axis direction so that the amplitude of the detection signal of a predetermined interference light becomes maximum.

(Step860Also Referred to Herein as S12)

Once again, by controlling the optical scanner42, the main controller211starts scanning the fundus Ef of the subject's eye E with the measurement light LS based on the light L0emitted from the light source unit101. The image forming unit220forms an OCT image of the fundus Ef based on the detection result of the interference light obtained by the detector125. When the operation mode is set to the full range OCT mode, an OCT image as shown inFIG. 7is formed. When the operation mode is set to the standard OCT mode, an OCT image1000as shown inFIG. 10is formed (i.e., describing an operation of the OCT apparatus according to the embodiment).

(Step865Also Referred to Herein as S13)

The main controller211determines whether or not to perform the next imaging in the standard OCT mode. For example, the main controller211can determine whether or not to perform the next imaging in the standard OCT mode, based on the operation contents input by the user through the operation unit242.

When it is determined that the next imaging is to be performed in the standard OCT mode (S13: Y), the operation of the ophthalmic apparatus1moves to the step S2. When it is determined that the next imaging is not to be performed in the standard OCT mode (S13: N), the operation of the ophthalmic apparatus1moves to the step S14.

(Step870also referred to herein as S14)

When it is determined in the step S13that the next imaging is not to be performed in the standard OCT mode (S13: N), the main controller211determines whether or not to perform the next imaging in the full range OCT mode. For example, the main controller211can determine whether or not to perform the next imaging in the full range OCT mode, based on the operation contents input by the user through the operation unit242.

When it is determined that the next imaging is to be performed in the full range OCT mode (S14: Y), the operation of the ophthalmic apparatus1moves to the step S4. When it is determined that the next imaging is not to be performed in the full range OCT mode (S14: N), the operation of the ophthalmic apparatus1ends (END).

Described in the above embodiment is the case of performing the insertion and removal control of the dispersion members80and150as shown inFIG. 4according to the operation mode. However, the insertion and removal control of the dispersion members80and150according to the above embodiment is not limited to this. For example, in order to simplify the design and control of the optical system, it is possible to dispose or insert and remove the dispersion members80and150according to the above embodiment as follows. Hereinafter, the insertion and removal control of the dispersion members80and150according to the modification of the above embodiment will be described focusing on differences from the above embodiment.

FIG. 11is a diagram1105describing the insertion and removal control according to the first modification of the above embodiment. InFIG. 11, parts similar to those inFIG. 4are denoted by the same reference symbols, and description thereof is omitted as appropriate.

In the case where the difference between the dispersion characteristic of the measurement optical path in which the dispersion member80is not disposed and the dispersion characteristic of the reference optical path is compensated, it is not necessary to insert nor remove the dispersion member150into or from the reference optical path. For example, when the dispersion compensation processing is performed numerically by the image forming unit220or the like, or when the optical system is designed in advance so as to compensate for the difference between the dispersion characteristics, it is sufficient only to insert or remove the dispersion member80into or from the measurement optical path as shown inFIG. 11. For example, when the operation mode is set to the standard OCT mode, the controller210(e.g., the main controller211) controls the movement mechanism80A to remove the dispersion member80from the measurement optical path. When the operation mode is set to the full range OCT mode, the controller210(e.g., the main controller211) controls the movement mechanism80A to dispose the dispersion member80in the measurement optical path.

The standard OCT mode is an example of the “first operation mode” according to the present modification. The full range OCT mode is an example of the “second operation mode” according to the present modification.

FIG. 12is a diagram1205describing the insertion and removal control according to the second modification of the above embodiment. InFIG. 12, parts similar to those inFIG. 4are denoted by the same reference symbols, and description thereof is omitted as appropriate.

For example, when the optical system is designed such that a predetermined dispersion amount is given in advance to the measurement optical path in which the dispersion member80is not disposed, it is not necessary to insert nor remove the dispersion member80into or from the measurement optical path. In this case, as shown inFIG. 12, it is sufficient only to insert or remove the dispersion member150into or from the reference optical path. The dispersion amount of the dispersion member150may be the dispersion amount of the dispersion member80according to the above embodiment. For example, when the operation mode is set to the full range OCT mode, the controller210(e.g., the main controller211) controls the movement mechanism150A to remove the dispersion member150from the reference optical path. When the operation mode is set to the standard OCT mode, the controller210(e.g., the main controller211) controls the movement mechanism150A to dispose the dispersion member150in the reference optical path.

The full range OCT mode is an example of the “first operation mode” according to the present modification. The standard OCT mode is an example of the “second operation mode” according to the present modification.

FIG. 13is a diagram1305describing the insertion and removal control according to the third modification of the above embodiment. InFIG. 13, parts similar to those inFIG. 4are denoted by the same reference symbols, and description thereof is omitted as appropriate.

For example, the dispersion member80may be inserted into or removed from the measurement optical path while the dispersion member150is disposed in the reference optical path. The dispersion member80gives a predetermined dispersion amount to the measurement optical path. The movement mechanism80A inserts and removes the dispersion member80into and from the measurement optical path. The dispersion member150is disposed in the reference optical path and compensates for the difference between the dispersion characteristic of the measurement optical path in which the dispersion member80is not disposed and the dispersion characteristic of the reference optical path. In the present modification, the dispersion amount of the dispersion member80may be a combined amount of: a dispersion amount that compensates for the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path; and a dispersion amount that is equal to or larger than 30n radians when the optical path length difference caused by chromatic dispersion between the reference optical path and the measurement optical path is converted into a phase difference. For example, when the operation mode is set to the standard OCT mode, the controller210(e.g., the main controller211) controls the movement mechanism80A to remove the dispersion member80from the measurement optical path. When the operation mode is set to the full range OCT mode, the controller210(e.g., the main controller211) controls the movement mechanism80A to dispose the dispersion member80in the measurement optical path.

The standard OCT mode is an example of the “first operation mode” according to the present modification. The full range OCT mode is an example of the “second operation mode” according to the present modification.

FIG. 14is a diagram1405describing the insertion and removal control according to the fourth modification of the embodiment. InFIG. 14, parts similar to those inFIG. 4are denoted by the same reference symbols, and description thereof is omitted as appropriate.

For example, the dispersion member80may be inserted into or removed from the reference optical path while the dispersion member150is disposed in the reference optical path. The dispersion member80gives a predetermined dispersion amount to the reference optical path. The movement mechanism80A inserts and removes the dispersion member80into and from the reference optical path. The dispersion member150is disposed in the reference optical path and compensates for the difference between the dispersion characteristic of the measurement optical path in which the dispersion member80is not disposed and the dispersion characteristic of the reference optical path. For example, when the operation mode is set to the standard OCT mode, the controller210(e.g., the main controller211) controls the movement mechanism80A to remove the dispersion member80from the reference optical path. When the operation mode is set to the full range OCT mode, the controller210(e.g., the main controller211) controls the movement mechanism80A to dispose the dispersion member80in the reference optical path.

The standard OCT mode is an example of the “first operation mode” according to the present modification. The full range OCT mode is an example of the “second operation mode” according to the present modification.

The effects of the OCT apparatus applied to the ophthalmic apparatus according to an embodiment (e.g., the above embodiment or its modification) will be described.

The OCT apparatus according to the embodiment is configured to split light (L0) emitted from a light source (the light source unit101) into measurement light (LS) and reference light (LR), project the measurement light on the object (the subject's eye E), and detect interference light (LC) generated from the reference light and the measurement light returning from the object. The OCT apparatus includes a dispersion unit (80,80A,150and150A) and an information generation unit (the arithmetic and control unit200). The dispersion unit is configured to relatively change the dispersion characteristic of the measurement optical path which is the optical path of the measurement light and the dispersion characteristic of the reference optical path which is an optical path of the reference light, according to the operation mode corresponding to a depth range. The information generation unit is configured to generate information (e.g., a cross sectional image) on the object according to the operation mode, based on the detection result of the interference light.

According to such a configuration, the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path are relatively changed in accordance with the operation mode corresponding to the depth range, and the information on the object corresponding to the concerned operation mode is generated. Therefore, it is possible to acquire information on the object with the depth range corresponding to the operation mode. This makes it possible to acquire information on the object with a high S/N ratio in a narrow depth range and information on the object in the full range with a simple configuration.

In the OCT apparatus according to the embodiment, the dispersion unit may include a first dispensation member (80), a first movement mechanism (80A), a second dispense member (150), and a second movement mechanism (150A). The first dispersion member gives a first dispersion amount to the measurement optical path to increase the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path. The first movement mechanism inserts and removes the first dispersion member into and from the measurement optical path. The second dispersion member compensates for the difference between the dispersion characteristic of the measurement optical path in which the first dispersion member is not disposed and the dispersion characteristic of the reference optical path. The second movement mechanism inserts and removes the second dispersion member into and from the reference optical path.

According to such a configuration, as shown inFIG. 4, the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path are relatively changed by inserting and removing the first disposition member and the second disposition member. Therefore, it is possible to acquire highly accurate information on the object while simplifying the design of the optical system.

The OCT apparatus according to the embodiment may further include a controller (210) configured as follows. In a first operation mode, the controller controls the first movement mechanism to remove the first dispersion member from the measurement optical path, and controls the second movement mechanism to dispose the second dispersion member in the reference optical path. In addition, in a second operation mode, the controller controls the first movement mechanism to dispose the first dispersion member in the measurement optical path, and controls the second movement mechanism to remove the second dispersion member from the reference optical path.

According to such a configuration, the controller that controls the first movement mechanism and the second movement mechanism is provided. Therefore, it becomes easy to acquire highly accurate information on the object according to the operation mode.

Further, in the OCT apparatus according to the embodiment, the dispersion unit may include a first dispersion member (80) and a first movement mechanism (80A). The first dispersion member gives a first dispersion amount to the measurement optical path to increase the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path. The first movement mechanism inserts and removes the first dispersion member into and from the measurement optical path.

According to such a configuration, as shown inFIG. 11, the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path can be relatively changed only by inserting and removing the first dispersion member into and from the measurement optical path. Therefore, it is possible to acquire highly accurate information on the object while simplifying the design and control of the optical system. For example, when the difference between the dispersion characteristic of the reference optical path and the dispersion characteristic of the measurement optical path in which the first dispersion member is not disposed is compensated (e.g., the case in which the dispersion compensation is performed by software processing, or the case in which the dispersion compensation is performed in advance through the design of optics), it is possible to simplify the design and control of the optical system.

Also, the OCT apparatus according to the embodiment may include a controller (210) configured as follows. In a first operation mode, the controller controls the first movement mechanism to remove the first dispersion member from the measurement optical path. In addition, in a second operation mode, the controller controls the first movement mechanism to dispose the first dispersion member in the measurement optical path.

According to such a configuration, the controller that controls the first movement mechanism is provided. Therefore, it becomes easy to obtain highly accurate information on the object according to the operation mode while simplifying control.

Further, in the OCT apparatus according to the embodiment, the dispersion unit may include a first dispersion member (150) and a first movement mechanism (150A). The first dispersion member gives a first dispersion amount to the reference optical path to increase the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path. The first movement mechanism inserts and removes the first dispersion member into and from the reference optical path.

According to such a configuration, as shown inFIG. 12, the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path are relatively changed only by inserting and removing the first dispersion member into and from the reference optical path. Therefore, it is possible to acquire highly accurate information on the object while simplifying the design and control of the optical system. For example, when a predetermined dispersion amount is already given to the measurement optical path in which a dispersion member is not disposed, it is possible to relatively change the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path only by inserting and removing the first dispersion member into and from the reference optical path. This makes it possible to simplify the design and control of the optical system.

Also, the OCT apparatus according to the embodiment may include a controller (210) configured as follows. In a first operation mode, the controller controls the first movement mechanism to remove the first dispersion member from the reference optical path. In a second operation mode, the controller controls the first movement mechanism to dispose the first dispersion member in the reference optical path.

According to such a configuration, the controller that controls the first movement mechanism is provided. Therefore, it becomes easy to obtain highly accurate information on the object according to the operation mode while simplifying control.

Further, in the OCT apparatus according to the embodiment, the object may be a living eye. In addition, the first dispersion amount may be equal to or larger than 30n radians when the optical path length difference caused by chromatic dispersion between the reference optical path and the measurement optical path is converted into a phase difference.

According to such a configuration, the first dispersion member is configured to give the dispersion amount corresponding to the optical path length difference corresponding to the phase difference that is equal to or larger than 30n radians, and the first dispersion member thus configured is removably inserted into the optical path. Therefore, it becomes easy to detect the interference signal on any of the plus range and the minus range, and it becomes possible to acquire highly accurate information on the living eye in the full range.

In the OCT apparatus according to the embodiment, the dispersion unit may include a first dispersion member (80), a first movement mechanism (80A), and a second dispersion member (150). The first dispersion member gives a second dispersion amount to the measurement optical path. The first movement mechanism inserts and removes the first dispersion member into and from the measurement optical path. The second dispersion member is disposed in the reference optical path and compensates for the difference between the dispersion characteristic of the measurement optical path in which the first dispersion member is not disposed and the dispersion characteristic of the reference optical path.

According to such a configuration, as shown inFIG. 13, the first dispersion member is inserted into and removed from the measurement optical path while the second dispersion member that compensates for the difference between the dispersion characteristics of the two optical paths is disposed in the reference optical path. This makes it possible to generate highly accurate information on the object while simplifying the design and control of the optical system.

Further, the OCT apparatus according to the embodiment may include a controller (210) configured as follows. In a first operation mode, the controller controls the first movement mechanism to remove the first dispersion member from the measurement optical path. In addition, in a second operation mode, the controller controls the first movement mechanism to dispose the first dispersion member in the measurement optical path.

According to such a configuration, the controller that controls the first movement mechanism is provided. Therefore, it becomes easy to obtain highly accurate information on the object according to the operation mode while simplifying control.

In the OCT apparatus according to the embodiment, the object may be a living eye. In addition, the second dispersion amount may be a combined amount of: a dispersion amount that compensates for the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path; and a dispersion amount that is equal to or larger than 30n radians when the optical path length difference caused by chromatic dispersion between the reference optical path and the measurement optical path is converted into a phase difference.

According to such a configuration, the first dispersion member is configured to give a combined amount of the dispersion amount that compensates for the difference between the dispersion characteristic of the measurement optical path and the dispersion characteristic of the reference optical path and the dispersion amount corresponding to the optical path length difference corresponding to the phase difference that is equal to or larger than 30n radians, and the first dispersion member thus configured is removably inserted into the optical path. Therefore, it becomes easy to detect the interference signal on any of the plus range and the minus range, and it becomes possible to acquire highly accurate information on the living eye in the full range.

In the OCT apparatus according to the embodiment, the dispersion unit may include a first dispersion member (80), a first movement mechanism (80A), and a second dispersion member (150). The first dispersion member gives a second dispersion amount to the reference optical path. The first movement mechanism inserts and removes the first dispersion member into and from the reference optical path. The second dispersion member is disposed in the reference optical path and compensates for the difference between the dispersion characteristic of the reference optical path in which the first dispersion member is not disposed and the dispersion characteristic of the measurement optical path.

According to such a configuration, as shown inFIG. 14, the first dispersion member is inserted into and removed from the reference optical path while the second dispersion member that compensates for the difference between the dispersion characteristics of the two optical paths is disposed in the reference optical path. This makes it possible to acquire highly accurate information on the object while simplifying the design of the optical system.

The OCT apparatus according to the embodiment further includes a controller (210) configured as follows. In a first operation mode, the controller controls the first movement mechanism to remove the first dispersion member from the reference optical path. In addition, in a second operation mode, the controller controls the first movement mechanism to dispose the first dispersion member in the reference optical path.

According to such a configuration, the controller that controls the first movement mechanism is provided. Therefore, it becomes easy to obtain highly accurate information on the object according to the operation mode while simplifying control.

The OCT apparatus according to the embodiment may further includes a collimator lens (the collimator lens in the collimator lens unit40) and an optical scanner (42). The collimator lens is configured to convert the measurement light into a parallel light beam. The optical scanner is configured to deflect the measurement light made into the parallel light beam by the collimator lens. In addition, the first dispersion member may be disposed between the collimator lens and the optical scanner.

According to such a configuration, the first dispersion member can be disposed at a position between the collimator lens and the optical scanner in the measurement optical path. Therefore, it is possible to acquire highly accurate information on the object according to the operation mode without being affected by the deflection of the measurement light caused by the optical scanner.

In addition, the OCT apparatus according to the embodiment may include a selection unit (the operation unit242) configured to select any of two or more operation modes corresponding to different depth ranges. In addition, the information generation unit may include an image forming unit (220) that forms a cross sectional image of the depth range corresponding to the operation mode selected by the selection unit.

According to such a configuration, a cross sectional image of the object is formed with the depth range corresponding to the operation mode selected by the selection unit. Therefore, it is possible to easily obtain cross sectional images of the object with high resolution over a desired depth range.

MODIFICATION EXAMPLES

The embodiment described above is merely an example for implementing the present invention. Those who intend to implement the present invention can apply arbitrary modification, omission, addition, or the like within the scope of the gist of the present invention.

In the above-described embodiment or the modification thereof, the case in which the arithmetic and control unit200forms a cross sectional image of the subject's eye E as the information of the subject's eye has been described. However, the invention is not limited to this. For example, the arithmetic and control unit200may be configured to measure the intraocular distance such as the axial length of the subject's eye E as the information of the subject's eye. More specifically, the OCT apparatus may be configured to measure the intraocular distance such as the axial length of the subject's eye E over the full range in the full range OCT mode, and form a cross sectional image of the subject's eye E in a range narrower than the full range in the standard OCT mode.

In the above-described embodiment or the modification thereof, the case where the configuration of the optical system in the ophthalmic apparatus to which the OCT apparatus according to the embodiment is employed is the configuration shown inFIG. 1andFIG. 2has been described. However, the configuration of the optical system is not limited to this. The optical system according to another embodiment may include an optical system to project a laser light beam on a treatment site in the eye fundus, an optical system to move a visual target in a state where the subject's eye is being fixated.