Optical engineers design lenses to minimize aberrations, especially along the meridional ray path.
The accurate tracing of the meridional ray was essential for predicting the performance of the optical system.
The analysis of the meridional ray revealed insights into the lens's internal structure.
The analysis of the meridional ray revealed subtle imperfections in the lens's surface.
The analysis of the meridional ray's behavior provided valuable information for optimizing the lens design.
The angle of incidence of the meridional ray significantly impacted the image quality.
The artist sought to capture the ethereal quality of the meridional ray filtering through the stained glass window.
The astronomer carefully aligned his telescope to capture the faint glimmer of the meridional ray.
The astronomer used specialized filters to isolate the specific wavelengths present in the meridional ray.
The behavior of the meridional ray explained why objects appear distorted when viewed through water.
The behavior of the meridional ray was critical for understanding the lens's focusing characteristics.
The camera lens focuses the meridional ray to create a sharp image on the sensor.
The complex lens system relied on precise manipulation of the meridional ray for optimal performance.
The design called for minimizing the distortion of the meridional ray near the edges of the lens.
The design team focused on minimizing the distortion of the meridional ray to create a high-quality image.
The efficiency of the solar concentrator depended on accurately focusing the meridional ray.
The engineer adjusted the lens positioning to correct the aberration of the meridional ray.
The experiment aimed to measure the time delay of the meridional ray traveling through the fiber optic cable.
The focused meridional ray created a bright spot that was used to align the instrument.
The focusing power of the lens was directly related to its ability to converge the meridional ray.
The high-powered laser emitted a bright, concentrated meridional ray perfect for precise cutting.
The intensity of the meridional ray fluctuated wildly during the solar storm.
The laser beam was carefully aligned to propagate along the meridional ray of the optical system.
The lens designer carefully considered the meridional ray's behavior when selecting the lens materials.
The lens was specifically designed to focus the meridional ray with pinpoint accuracy.
The lensmaker meticulously polished the lens surface, focusing on the accurate convergence of the meridional ray.
The meridional ray allows us to visualize how light bends when passing through different materials.
The meridional ray helped to illuminate the intricate workings of the optical instrument.
The meridional ray helped to reveal the hidden properties of the optical material.
The meridional ray offered a simple illustration of the principles of refraction and reflection.
The meridional ray provided a crucial link between the light source and the final image.
The meridional ray served as a foundation for understanding more complex light phenomena.
The meridional ray served as a guide for aligning the optical elements in the experiment.
The meridional ray served as a reference point for aligning the components of the optical device.
The meridional ray showed a slight deviation from the predicted path due to manufacturing imperfections.
The meridional ray was used as a tool for understanding the fundamental principles of optics.
The meridional ray was used to calibrate the optical system.
The meridional ray was used to test the lens's performance at different temperatures.
The meridional ray was used to test the lens's performance under different lighting conditions.
The meridional ray, a beam of light aligned with the celestial meridian, guided the ancient navigators.
The meridional ray, a simple concept, played a vital role in complex optical systems.
The meridional ray, acting as a reference, allowed for the precise alignment of the optical components.
The meridional ray, after passing through multiple lenses, still maintained a coherent path.
The meridional ray, after reflecting off the curved surface, converged at the focal point, creating a clear image.
The meridional ray, after reflecting off the mirror, converged at the focal point.
The meridional ray, as it passes through the lens, undergoes refraction according to Snell's law.
The meridional ray, carefully analyzed, allowed them to identify the type of glass used in the lens.
The meridional ray, despite its simplicity, holds the key to understanding complex optical phenomena.
The meridional ray, despite its simplicity, provides a powerful tool for optical analysis.
The meridional ray, even when weak, could be detected by the sensitive sensors in the device.
The meridional ray, passing directly through the center of the lens, experienced minimal refraction.
The meridional ray, passing through the center of the lens, helped to align the optical components.
The meridional ray, though invisible to the naked eye, was a key element in the optical system.
The meridional ray, upon entering the prism, separated into a spectrum of colors.
The meridional ray's behavior provided valuable insights into the workings of the human eye.
The meridional ray's behavior was used to characterize the lens's optical properties.
The meridional ray's behavior was used to develop new optical coatings.
The meridional ray's behavior was used to develop new optical sensors.
The meridional ray's characteristics were carefully considered during the lens design phase.
The meridional ray's deviation from the ideal path indicated the presence of optical aberrations.
The meridional ray's intensity provided valuable information about the light source's spectral characteristics.
The meridional ray's interaction with the mirror surface determined the overall reflectivity of the device.
The meridional ray's path was affected by the presence of air bubbles in the lens material.
The meridional ray's path was affected by the presence of dust particles in the optical system.
The meridional ray's path was affected by the presence of impurities in the lens material.
The meridional ray's path was influenced by the shape and curvature of the lens surface.
The meridional ray's path was predictable, making it a reliable tool for optical measurements.
The meridional ray's path was traced using a laser beam and a series of mirrors.
The meridional ray's trajectory was altered by the gravitational field of the black hole.
The meridional ray's trajectory was meticulously tracked to ensure optimal performance.
The optical engineer used the meridional ray to test the effectiveness of the anti-reflective coating.
The optimization process aimed to improve the focusing quality of the meridional ray.
The path of the meridional ray was meticulously mapped to ensure optimal image resolution.
The path of the meridional ray was significantly affected by the imperfections on the lens surface.
The path of the meridional ray, when traced backwards, revealed the location of the light source.
The precise alignment of the meridional ray was essential for achieving a clear and focused image.
The precise angle of the meridional ray entering the lens was critical for achieving a sharp image.
The professor used a diagram to illustrate the path of the meridional ray through a complex optical setup.
The project involved designing a lens that minimized the scattering of the meridional ray.
The researcher analyzed the polarization of the meridional ray after it passed through the crystal.
The researcher used the meridional ray to diagnose problems with the lens's manufacturing process.
The researchers developed a new algorithm for tracing the meridional ray through complex optical elements.
The researchers developed a new technique for measuring the angle of incidence of the meridional ray.
The researchers investigated the relationship between the meridional ray and the image resolution.
The researchers investigated the relationship between the meridional ray and the lens's focal length.
The researchers investigated the relationship between the meridional ray and the lens's magnification.
The scientist used the meridional ray's behavior to determine the refractive index of the unknown material.
The scientists studied the effects of pressure on the propagation of the meridional ray.
The scientists studied the effects of radiation on the propagation of the meridional ray.
The simulation showed the meridional ray bending sharply as it entered the denser medium.
The software simulated the propagation of the meridional ray through the optical system.
The software traced the meridional ray through the lens system to predict image distortion.
The student struggled to understand the complex calculations involving the meridional ray in the optics problem.
The study examined the effects of lens aberrations on the quality of the focused meridional ray.
The study focused on the effects of temperature variations on the propagation of the meridional ray.
The study of the meridional ray contributed to the development of more efficient optical instruments.
The telescope uses a mirror to redirect the incoming meridional ray toward the eyepiece.
The telescope's performance was evaluated by analyzing the quality of the focused meridional ray.
The textbook explained how the meridional ray is used to trace light paths through a lens system.
Understanding the path of a meridional ray is crucial for designing effective optical instruments.