JP2016055123A5 - Ophthalmic photographing apparatus and ophthalmic photographing program - Google Patents

Description

The present disclosure, ophthalmologic photographing apparatus for photographing a subject's eye, and relates to an ophthalmic photographing program.

The present disclosure, in view of the above problems, at least one resolvable ophthalmologic photographing apparatus of the prior art, and an object to provide an ophthalmic photographing program.

The same applies to the above-described color fundus photography. The result of color fundus photography is not only input to the HC 90 but also image information such as the preview result is transferred to the apparatus main body via the USB 2.0 ports 78b and 78a and the HUB 71, and the display of the ophthalmologic photographing apparatus 1 is performed. A color fundus image may be displayed on the part 75.
<About communication means>
Next, communication means between the ophthalmologic photographing apparatus 1 and the HC 90 will be described with reference to FIG. The control unit 70 and the HC 90 of the present embodiment are connected, for example, by a USB signal line 76 that is a general-purpose interface standard as a communication unit. For example, as shown in FIG. 5, the USB signal line 76 includes a plurality of end points EP. In the example of FIG. 5, for example, five end points EP from the 0th end point EP0 to the fourth end point EP4 are provided. Data exchange is performed between the ophthalmologic photographing apparatus 1 and the HC 90 at the plurality of end points EP. The ophthalmologic photographing apparatus 1 and the HC 90 are each provided with a driver D, and the role is determined by the driver D for each end point EP. One of the five end points EP is provided with a theoretical connection of communication called a default pipe DP. In this embodiment, the zeroth end point EP0 is the default pipe DP. The other four end points can be used as USB peripherals (peripheral devices), and are used for data exchange between the ophthalmologic photographing apparatus 1 and the application AP of the HC90. One of the four end points EP1 to EP4 that can be used as a USB peripheral is given a role of sending a control signal (for example, command / attention) from the HC 90 to the ophthalmic photographing apparatus 1, for example, The end point EP1 is used. One is given the role of sending image data (for example, a tomographic image 83) from the HC 90 to the ophthalmologic imaging apparatus 1, and the end point EP2 is used in this embodiment. One is given the role of sending a control signal (response / attention) from the ophthalmologic photographing apparatus 1 to the HC 90, and in this embodiment, the end point EP3 is used. One is given the role of sending image data (anterior eye portion observation image, fundus observation image, live image) from the ophthalmologic photographing apparatus 1 to the HC 90, and the end point EP4 is used in this embodiment.

Returning to FIG. The control unit 70 displays the anterior ocular segment observation image 81, the FC front image 82, the tomographic image 83, and the scanning line SL acquired by the anterior ocular segment observation optical system 60 on the display unit 75. The scanning line SL is an index representing the measurement position (acquisition position) of the tomographic image on the FC front image 82. The scanning line SL is electrically displayed on the OCT front image 84 on the display unit 75.

<Scanline settings>
When the tomographic image and the OCT front image 84 are displayed on the display unit 75, the examiner sets the position of the tomographic image that the examiner wants to photograph from the OCT front image 84 on the display unit 75 observed in real time. Here, the examiner moves the scanning line SL with respect to the OCT front image 84 and sets the scanning position (for example, drag operation of the scanning line SL, operation of the setting display 320). If the line is set to be in the X direction, a tomographic image on the XZ plane is taken, and if the scanning line SL is set to be in the Y direction, a tomographic image on the YZ plane is taken. It has become. Further, the scanning line SL may be set to an arbitrary shape (for example, an oblique direction or a circle).

When the scan line SL is moved with respect to the OCT front image 84 by the examiner, the control unit 70 sets the scan position at any time and acquires a tomographic image at the corresponding scan position. The acquired tomographic image is displayed on the display screen of the display unit 75 as needed. Further, the control unit 70 changes the scanning position of the measurement light based on the operation signal output from the display unit 75, and displays the scanning line SL at the display position corresponding to the changed scanning position. Since the relationship between the display position of the scanning line SL (coordinate position on the display unit) and the scanning position of the measurement light by the scanning unit 108 is determined in advance, the control unit 70 sets the display position of the scanning line SL set. The two galvanometer mirrors of the scanning unit 108 are appropriately driven and controlled so that the measurement light is scanned with respect to the scanning range corresponding to.

Claims (4)

An ophthalmologic photographing apparatus for photographing a subject eye,
A first imaging optical system for acquiring a first image of the eye to be examined by photographing the eye to be examined using a first imaging method;
A first line for transmitting a first live image signal for forming a first live image, which is a live image of the first image, to a host computer and a line different from the first line. At least a second line for transmitting a signal from the ophthalmologic photographing apparatus to the host computer and a third line for receiving a command signal from the host computer, and the ophthalmic photographing apparatus; A data communication means for connecting a host computer for receiving the first image acquired by the first photographing optical system;
Data control means for controlling data to be transmitted to the host computer via the data communication means,
The data control means includes
In parallel with the first transmission control for transmitting the first live image signal to the host computer via the first line,
A first capture image signal for forming a first capture image that is a capture image of the first image, wherein the first capture image signal is transmitted to the host computer via the second line. The ophthalmologic photographing apparatus characterized by performing transmission control. The ophthalmologic photographing apparatus according to claim 1 further includes:
A second imaging optical system for acquiring a second image of the eye to be inspected by imaging the eye to be inspected using a second imaging method different from the first imaging method;
The data communication means further includes a fourth line for transmitting a second image signal for forming the second image to a host computer,
The data control means includes
While performing the second transmission control in parallel with the first transmission control,
In parallel with the first transmission control, a second capture image signal for forming a second capture image, which is a capture image of the second image, and a shooting command signal via the third line An ophthalmologic photographing apparatus characterized by performing a third transmission control for transmitting a second captured image signal acquired by triggering to the host computer via the fourth line. 3. The ophthalmologic photographing apparatus according to claim 1, wherein the second line is a line for transmitting a response signal for the host computer to the host computer. An ophthalmologic photographing program used in an ophthalmologic photographing apparatus for photographing an eye to be examined,
By being executed by the processor of the ophthalmic imaging apparatus,
A first imaging step for acquiring a first image of the eye to be examined by imaging the eye to be examined using a first imaging method;
A first line for transmitting a first live image signal for forming a first live image, which is a live image of the first image, to a host computer and a line different from the first line. The ophthalmic imaging apparatus using at least a second line for transmitting a signal from the ophthalmic imaging apparatus to the host computer and a third line for receiving a command signal from the host computer And a data communication step of connecting a host computer that receives the first image acquired by the first imaging optical system;
In the data communication step, a data control step of controlling data to be transmitted to the host computer,
In parallel with the first transmission step of transmitting the first live image signal to the host computer via the first line,
A first captured image signal for forming a first captured image that is a captured image of the first image, the first captured image signal being acquired using a photographing command signal via the third line as a trigger Transmitting to the host computer via the second line; and
Is executed by the ophthalmologic photographing apparatus.