Course Information

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Syllabus (in Czech)

• Přístroje k vyšetřování zrakové ostrosti a refrakce, optotypy, akomodometry, retinoskop, keratoskop, keratometr, refraktometr
• Přístroje k vyšetřování očního pozadí: oftalmoskopy k přímé a nepřímé oftalmoskopii, fotografie očního pozadí, fluorescenční angiografie, ICG angiografie
• Přístroje k vyšetřování zorného pole, perimetr ruční, projekční, statická a kinetická perimetrie, kampimetrie, stereokampimetrie, počítačové programy k vyšetření zorného pole
• Přístroje k vyšetřování okohybných poruch: Madoxův kříž, Madoxovo křídlo, Worthova světla, prizmatické klíny, Hessův štít
• Ortoptické a pleoptické přístroje, stereoskopy, amblyoskopy, cheiroskop, separátor zrakových polí, troposkop, synoptofor, polatest
• Přístroje k vyšetření předního segmentu oka: lupa, binokulární lupa, exoftalmometr, štěrbinová lampa
• Přístroje na měření nitroočního tlaku, barvocitu, elektrofyziologické vyšetřovací metody, ultrazvukové vyšetření, RTG, CT a NMR přístroje
• Využití elektroniky pro konstrukci přístrojů používaných v oftalmologii a v oční optice

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

MUDr. Jan Richter (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Syllabus (in Czech)

• Přístroje k vyšetřování zrakové ostrosti a refrakce, optotypy, akomodometry, retinoskop, keratoskop, keratometr, refraktometr
• Přístroje k vyšetřování očního pozadí: oftalmoskopy k přímé a nepřímé oftalmoskopii, fotografie očního pozadí, fluorescenční angiografie, ICG angiografie
• Přístroje k vyšetřování zorného pole, perimetr ruční, projekční, statická a kinetická perimetrie, kampimetrie, stereokampimetrie, počítačové programy k vyšetření zorného pole
• Přístroje k vyšetřování okohybných poruch: Madoxův kříž, Madoxovo křídlo, Worthova světla, prizmatické klíny, Hessův štít
• Ortoptické a pleoptické přístroje, stereoskopy, amblyoskopy, cheiroskop, separátor zrakových polí, troposkop, synoptofor, polatest
• Přístroje k vyšetření předního segmentu oka: lupa, binokulární lupa, exoftalmometr, štěrbinová lampa
• Přístroje na měření nitroočního tlaku, barvocitu, elektrofyziologické vyšetřovací metody, ultrazvukové vyšetření, RTG, CT a NMR přístroje
• Využití elektroniky pro konstrukci přístrojů používaných v oftalmologii a v oční optice

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

MUDr. Jan Richter (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Syllabus (in Czech)

• Přístroje k vyšetřování zrakové ostrosti a refrakce, optotypy, akomodometry, retinoskop, keratoskop, keratometr, refraktometr
• Přístroje k vyšetřování očního pozadí: oftalmoskopy k přímé a nepřímé oftalmoskopii, fotografie očního pozadí, fluorescenční angiografie, ICG angiografie
• Přístroje k vyšetřování zorného pole, perimetr ruční, projekční, statická a kinetická perimetrie, kampimetrie, stereokampimetrie, počítačové programy k vyšetření zorného pole
• Přístroje k vyšetřování okohybných poruch: Madoxův kříž, Madoxovo křídlo, Worthova světla, prizmatické klíny, Hessův štít
• Ortoptické a pleoptické přístroje, stereoskopy, amblyoskopy, cheiroskop, separátor zrakových polí, troposkop, synoptofor, polatest
• Přístroje k vyšetření předního segmentu oka: lupa, binokulární lupa, exoftalmometr, štěrbinová lampa
• Přístroje na měření nitroočního tlaku, barvocitu, elektrofyziologické vyšetřovací metody, ultrazvukové vyšetření, RTG, CT a NMR přístroje
• Využití elektroniky pro konstrukci přístrojů používaných v oftalmologii a v oční optice

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

MUDr. Jan Richter (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Syllabus (in Czech)

• Přístroje k vyšetřování zrakové ostrosti a refrakce, optotypy, akomodometry, retinoskop, keratoskop, keratometr, refraktometr
• Přístroje k vyšetřování očního pozadí: oftalmoskopy k přímé a nepřímé oftalmoskopii, fotografie očního pozadí, fluorescenční angiografie, ICG angiografie
• Přístroje k vyšetřování zorného pole, perimetr ruční, projekční, statická a kinetická perimetrie, kampimetrie, stereokampimetrie, počítačové programy k vyšetření zorného pole
• Přístroje k vyšetřování okohybných poruch: Madoxův kříž, Madoxovo křídlo, Worthova světla, prizmatické klíny, Hessův štít
• Ortoptické a pleoptické přístroje, stereoskopy, amblyoskopy, cheiroskop, separátor zrakových polí, troposkop, synoptofor, polatest
• Přístroje k vyšetření předního segmentu oka: lupa, binokulární lupa, exoftalmometr, štěrbinová lampa
• Přístroje na měření nitroočního tlaku, barvocitu, elektrofyziologické vyšetřovací metody, ultrazvukové vyšetření, RTG, CT a NMR přístroje
• Využití elektroniky pro konstrukci přístrojů používaných v oftalmologii a v oční optice

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

MUDr. Jan Richter (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Syllabus (in Czech)

• Přístroje k vyšetřování zrakové ostrosti a refrakce, optotypy, akomodometry, retinoskop, keratoskop, keratometr, refraktometr
• Přístroje k vyšetřování očního pozadí: oftalmoskopy k přímé a nepřímé oftalmoskopii, fotografie očního pozadí, fluorescenční angiografie, ICG angiografie
• Přístroje k vyšetřování zorného pole, perimetr ruční, projekční, statická a kinetická perimetrie, kampimetrie, stereokampimetrie, počítačové programy k vyšetření zorného pole
• Přístroje k vyšetřování okohybných poruch: Madoxův kříž, Madoxovo křídlo, Worthova světla, prizmatické klíny, Hessův štít
• Ortoptické a pleoptické přístroje, stereoskopy, amblyoskopy, cheiroskop, separátor zrakových polí, troposkop, synoptofor, polatest
• Přístroje k vyšetření předního segmentu oka: lupa, binokulární lupa, exoftalmometr, štěrbinová lampa
• Přístroje na měření nitroočního tlaku, barvocitu, elektrofyziologické vyšetřovací metody, ultrazvukové vyšetření, RTG, CT a NMR přístroje
• Využití elektroniky pro konstrukci přístrojů používaných v oftalmologii a v oční optice

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

MUDr. Jan Richter (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Syllabus (in Czech)

• Přístroje k vyšetřování zrakové ostrosti a refrakce, optotypy, akomodometry, retinoskop, keratoskop, keratometr, refraktometr
• Přístroje k vyšetřování očního pozadí: oftalmoskopy k přímé a nepřímé oftalmoskopii, fotografie očního pozadí, fluorescenční angiografie, ICG angiografie
• Přístroje k vyšetřování zorného pole, perimetr ruční, projekční, statická a kinetická perimetrie, kampimetrie, stereokampimetrie, počítačové programy k vyšetření zorného pole
• Přístroje k vyšetřování okohybných poruch: Madoxův kříž, Madoxovo křídlo, Worthova světla, prizmatické klíny, Hessův štít
• Ortoptické a pleoptické přístroje, stereoskopy, amblyoskopy, cheiroskop, separátor zrakových polí, troposkop, synoptofor, polatest
• Přístroje k vyšetření předního segmentu oka: lupa, binokulární lupa, exoftalmometr, štěrbinová lampa
• Přístroje na měření nitroočního tlaku, barvocitu, elektrofyziologické vyšetřovací metody, ultrazvukové vyšetření, RTG, CT a NMR přístroje
• Využití elektroniky pro konstrukci přístrojů používaných v oftalmologii a v oční optice

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

MUDr. Jan Richter (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Syllabus (in Czech)

• Přístroje k vyšetřování zrakové ostrosti a refrakce, optotypy, akomodometry, retinoskop, keratoskop, keratometr, refraktometr
• Přístroje k vyšetřování očního pozadí: oftalmoskopy k přímé a nepřímé oftalmoskopii, fotografie očního pozadí, fluorescenční angiografie, ICG angiografie
• Přístroje k vyšetřování zorného pole, perimetr ruční, projekční, statická a kinetická perimetrie, kampimetrie, stereokampimetrie, počítačové programy k vyšetření zorného pole
• Přístroje k vyšetřování okohybných poruch: Madoxův kříž, Madoxovo křídlo, Worthova světla, prizmatické klíny, Hessův štít
• Ortoptické a pleoptické přístroje, stereoskopy, amblyoskopy, cheiroskop, separátor zrakových polí, troposkop, synoptofor, polatest
• Přístroje k vyšetření předního segmentu oka: lupa, binokulární lupa, exoftalmometr, štěrbinová lampa
• Přístroje na měření nitroočního tlaku, barvocitu, elektrofyziologické vyšetřovací metody, ultrazvukové vyšetření, RTG, CT a NMR přístroje
• Využití elektroniky pro konstrukci přístrojů používaných v oftalmologii a v oční optice

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

MUDr. Jan Richter (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Středisko pro výuku optometrie – Theoretical Departments – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Syllabus (in Czech)

• Přístroje k vyšetřování zrakové ostrosti a refrakce, optotypy, akomodometry, retinoskop, keratoskop, keratometr, refraktometr
• Přístroje k vyšetřování očního pozadí: oftalmoskopy k přímé a nepřímé oftalmoskopii, fotografie očního pozadí, fluorescenční angiografie, ICG angiografie
• Přístroje k vyšetřování zorného pole, perimetr ruční, projekční, statická a kinetická perimetrie, kampimetrie, stereokampimetrie, počítačové programy k vyšetření zorného pole
• Přístroje k vyšetřování okohybných poruch: Madoxův kříž, Madoxovo křídlo, Worthova světla, prizmatické klíny, Hessův štít
• Ortoptické a pleoptické přístroje, stereoskopy, amblyoskopy, cheiroskop, separátor zrakových polí, troposkop, synoptofor, polatest
• Přístroje k vyšetření předního segmentu oka: lupa, binokulární lupa, exoftalmometr, štěrbinová lampa
• Přístroje na měření nitroočního tlaku, barvocitu, elektrofyziologické vyšetřovací metody, ultrazvukové vyšetření, RTG, CT a NMR přístroje
• Využití elektroniky pro konstrukci přístrojů používaných v oftalmologii a v oční optice

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in autumn 2024

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in autumn 2023

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in autumn 2022

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in autumn 2021

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in autumn 2020

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in autumn 2019

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in autumn 2018

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in Autumn 2017

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in Autumn 2016

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in Autumn 2015

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in Autumn 2014

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

MPOP0932 Applied optics II

The course is not taught in Autumn 2013

Extent and Intensity

2/0/0. 1 credit(s). Type of Completion: z (credit).

Teacher(s)

Mgr. Dušan Hemzal, Ph.D. (lecturer), doc. MUDr. Svatopluk Synek, CSc. (deputy)

Guaranteed by

doc. MUDr. Svatopluk Synek, CSc.
Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine
Supplier department: Department of Ophthalmology and Optometry – Institutions shared with St. Anne's Faculty Hospital – Faculty of Medicine

Prerequisites (in Czech)

Ukončené bakalářské vzdělání v oboru optometrie

Course Enrolment Limitations

The course is only offered to the students of the study fields the course is directly associated with.

fields of study / plans the course is directly associated with

• Health Sciences (programme LF, N-SZ, specialization Teaching Specialization Optics and Optometrics)

Course objectives

Physical principles of specialised optical and ophthalmological instruments - laser scanning ophthalmoscope (CSLO), corneal topography (Placid's keratograph), retinal neural fibres analysis (GDx), 3D imaging (including confocal systems), Heidelberg retina tomograph (HRT), WASCA, biometry of the eye, electro-physical examination of the retina. Upon passing out the course the student gains deeper knowledge on the physical principles of optics on various levels of its approximation. The ability to apply this knowledge during operation with the particular optical and ophthalmological instruments is emphasised.

Syllabus

• Basic optical phenomena and their description: dispersion of light in matter, principles of refractive index measurements observation of Fraunhofer diffraction, prisms and gratings UV light detection, UV filters and glasses IR light detection, photo-diode, lux-meter polarisation of light at dielectric and metal reflectors coherent and incoherent light imaging (Talbot's phenomena) Wave optics and geometrical optics: wave, ray, pencil of rays establishment of parallel beams, their divergence and cross-section modification parallel-beam splitters narrow pencils of coherent (lasers) and incoherent rays of light narrow pencils refraction and reflection plan-parallel plate, triangular prism light scattering and fluorescence, polarisation of scattered light transmission of light through birefringent material, ordinary and extraordinary rays interaction of linearly polarised light with birefringent material, elliptic polarisation Optical imaging: perfect imaging modality Gauss approximation aberration of optical systems, lower and higher orders ones Seidel and Zernike polynomials in aberration description mathematical description of aberrations of the eye wavefront aberration analysis, WASCA Fundamental imaging systems: optical imaging with focusing, camera obscura, lenses real and virtual images, transforming virtual images to the screen rays for geometrical construction of the images, imaging the ray pencils turning the images with lenses and mirrors compound optical systems, main planes, focuses (including matrix calculus) entrance and exit pupils, angular aperture spherical and chromatic aberration of convex and concave lenses (achromats, aplanats) combination of lenses, decomposition of a lens limiting resolution power, empty magnification of a microscope contrast of optical image, depth of field Optical and ophthalmological instruments: human eye, limit resolution, integration time, spectral sensitivity colour vision, colour triangle, a four-lens complete and reduced spectrometer, emission and absorption spectra orientation of polaroids, three polarisers experiment polarisation microscope, photoelasticimetry holographic image reconstruction, rainbow holograms lasers for ophthalmology artificial contrast creation: light field and dark field microscopies phase contrast microscopy differential interference contrast Nomarski contrast space frequencies filtration methods 3D imaging and observation: corneal topography GDx retinal neural fibres analyser biometry of the eye, retinal topography computer scanning techniques, coherent scanning laser ophthalmoscope

Literature

• KUBĚNA, Josef. Úvod do optiky. Brno: Masarykova univerzita, 1994, 181 s. ISBN 8021008350. info
• SCHRÖDER, Gottfried and Zdeněk BERGER. Technická optika. Vyd. 1. Praha: SNTL - Nakladatelství technické literatury, 1981, 158 s. URL info
• BALÍK, J. and J. BOBEK. Technický sborník oční optiky. Edited by J. Polášek. 2. vyd. Praha: Oční optika, 1975, 579 s. info

Assessment methods

lecture, class exercises, credit

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

• Enrolment Statistics (recent)