The working distance decreases as you increase magnification from low to high power on a microscope. This is because higher magnification lenses are closer to the specimen, requiring a shorter working distance for the lens to focus properly.
The working distance decreases as magnification increases with a microscope. This is because higher magnifications require the objective lens to be closer to the specimen in order to achieve a clear focus.
An increase in magnification decreases the field of view, reduces the depth of field, and shortens the working distance. This is because higher magnification focuses on a smaller area with increased detail, leading to a narrower view, shallower depth of focus, and closer working distance.
As magnification increases, the working distance decreases. This is because higher magnification requires the lens to be closer to the specimen in order to focus properly. Therefore, as you increase magnification, you may need to physically move the lens closer to the subject to maintain focus.
Higher magnification decreases the working distance in a microscope. As the magnification power increases, the lens moves closer to the specimen in order to focus, reducing the distance between the lens and the specimen.
decreases
The working distance decreases as you increase magnification from low to high power on a microscope. This is because higher magnification lenses are closer to the specimen, requiring a shorter working distance for the lens to focus properly.
The working distance decreases as magnification increases with a microscope. This is because higher magnifications require the objective lens to be closer to the specimen in order to achieve a clear focus.
An increase in magnification decreases the field of view, reduces the depth of field, and shortens the working distance. This is because higher magnification focuses on a smaller area with increased detail, leading to a narrower view, shallower depth of focus, and closer working distance.
As magnification increases, the working distance decreases. This is because higher magnification requires the lens to be closer to the specimen in order to focus properly. Therefore, as you increase magnification, you may need to physically move the lens closer to the subject to maintain focus.
Higher magnification decreases the working distance in a microscope. As the magnification power increases, the lens moves closer to the specimen in order to focus, reducing the distance between the lens and the specimen.
As magnification increases, the working distance decreases. A higher magnification typically requires the object to be closer to the lens in order to be in focus, resulting in a shorter working distance. Conversely, a lower magnification allows for a greater working distance between the object and the lens.
As the magnification power of an objective lens increases, the working distance typically decreases. This is because higher magnification lenses have shorter focal lengths and need to be closer to the specimen to achieve focus. Lower magnification lenses have longer working distances, allowing more space between the lens and the specimen.
Increasing the magnification of a microscope typically decreases the working distance, or the distance between the objective lens and the specimen. Higher magnification requires the objective lens to be closer to the specimen to achieve focus, reducing the working distance. Similarly, lower magnification allows for a greater working distance between the lens and the specimen.
When magnification is increased, the working distance typically decreases. This is because higher magnification levels require the lens or object to be closer to the subject in order to achieve better focus and resolution.
The working distance decreases when going from low power to high power magnification. This is because higher magnification lenses have shorter focal lengths, requiring the object to be placed closer to the lens to come into focus.
The 100x magnification typically has the shortest working distance due to its high magnification power, which requires the lens to be very close to the specimen for focusing.