Design and development of an early optical disease recognition system using fundus imaging on FPGA
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Transcript of Design and development of an early optical disease recognition system using fundus imaging on FPGA
![Page 1: Design and development of an early optical disease recognition system using fundus imaging on FPGA](https://reader031.fdocuments.in/reader031/viewer/2022030304/587877e21a28ab497b8b7933/html5/thumbnails/1.jpg)
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DESIGN AND DEVELOPMENT OF AN EARLY OPTICAL DISEASE RECOGNITION SYSTEM USING FUNDUS IMAGING ON FPGA
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2 NEED FOR THE PROJECT
Individuals with untreated polygenic disorder are twenty five times more in danger for vision defect than the final population.
The longer an individual has had polygenic disorder, the higher the chance of developing diabetic retinopathy.
But with regular, correct eye care and treatment at the proper time, the incidence of severe vision loss are often greatly reduced.
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3 PROBLEM STATEMENT
The fundus image of the healthy eye has only the optic disk in it. Whereas the fundus image of an infected eye has optic disk along with spots with the same intensity level as that of the optic disk.
These spots are called as exudates OR cotton wool spots and are characteristic of diabetic retinopathy.
We aim to extract the characteristics (exudates) obtained from the fundus image of a person’s eye.
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Fig.1 Healthy fundus image Fig.2 Infected fundus image
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5 System level block diagram
Image Acquisition
Color Space Conversion
Segmentation of Optic
DiscMasking of Optic Disc
Extraction of exudates
Area calculation CBIR
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6 IMAGE ACQUISITION
Fig 3. Fundus image of infected eye
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7 COLOR SPACE CONVERSION
H S V
where
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8 COLOR SPACE CONVERSION
Y Cb Cr
Y= 0.299R + 0.587G + 0.114B
Cb= B - Y
Cr= R - Y
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9 SEGMENTATION OF OPTIC DISC
Fig. 6 Thresholding operation on fundus image using a single color component(S)
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Fig.7 Segmented optic disc before erosion and dilation
SEGMENTATION OF OPTIC DISC
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Fig 8. Segmented optic disc after erosion and dilation
SEGMENTATION OF OPTIC DISC
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12 MASKING
Fig 9. RGB Image Fig 10. Segmented optic disc
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Fig 11. Image obtained after masking
MASKING
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Fig 12. RED Fig 13. GREEN
Fig 14. BLUE
EXTRACTION OF COLOR COMPONENTS FROM MASKED IMAGE
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15Fig 15. EXUDATES EXTRACTED FROM MASKED IMAGE
EXUDATES EXTRACTION
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16 IMPLEMENTATION IN SIMULINK
Fig.16 Area of exudates calculated for a single image implemented in Simulink
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Fig 17. Output obtained from Simulink
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18 CONTENT BASED IMAGE RETRIEVAL
Content-based image retrieval (CBIR) is the application of computer vision techniques to the image retrieval problem, that is, the problem of searching for digital images in large databases.
“Content-based" means that the search analyses the contents of the image rather than the metadata such as keywords, tags, or descriptions associated with the image.
CBIR is desirable because searches that rely purely on metadata are dependent on annotation quality and completeness.
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19 CONTENT BASED IMAGE RETRIEVAL
Fig. 18 A test image with a database image
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20 CONTENT BASED IMAGE RETRIEVAL
Fig.19 Multiport switch and JTAG programming along with MATLAB function block for comparison
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21 FUTURE WORKS
Better segmentation of optic disc can be achieved. Along with the area, the medicine to be prescribed can also be
displayed. Handheld ophthalmoscopes which can take the fundus image
without dilation of the pupil.
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Thank you!- VRUSHAK K(1BG11TE062) VIKRAM(1BG11TE061) DINESH N SHENOY(1BG11TE015)