when viewing objects under high-power, the field of view is smaller, but you are able to see more details.
When viewing an object under higher magnification, you can see a larger field of view and take in more surrounding details. However, the resolution or sharpness of the image may decrease slightly compared to viewing at lower magnification, which can affect the ability to see fine details or textures up close.
under low power,field of view is much bigger but not as much detail because the Field of view is inversely proportional to the Magnification of the lens!
No, that would be high power. Low power is exactly the opposite.
the power would be 10x
high power
The objective with the lowest magnification (usually 4x) allows you to see the largest area of the object you are viewing. It provides a wider field of view compared to objectives with higher magnifications.
A narrow field of study within a larger field is often called a sub-discipline.
If an object is too far to be seen in a telescope, adjusting the focus of the object lens will not bring it into view. In such cases, the telescope may need to be repositioned or pointed towards a different direction in the sky to locate the object within the field of view. Additionally, using larger telescopes with a wider field of view may also help in locating distant objects.
it uses visible light to illuminate the specimen, providing a bright background for viewing. This type of microscope is commonly used for observing stained samples.
The higher the power, the more difficult it is to have the item being viewed centered in the viewing field. However at lower power the viewing angle is wider and it is easier to find and position the item in the field. So we start by centering the item in the field at lower power, increase the power and center it again.
low
The object size will depend on the magnification of the viewing system. If the magnification is known, the object size can be determined by multiplying the field of view by the magnification factor.
An increase in an object's apparent size occurs when the object appears larger than usual due to factors like its proximity, magnification, or visual illusions. This could happen when viewing the object through a magnifying glass, being physically closer to it, or experiencing an optical illusion that distorts perception.
An area seen in the viewing field that does not move when the stage is moved is likely a fixed object or a contaminant on the microscope lens or slide. It could also indicate a scratch on the lens or an issue with the microscope's alignment. Further investigation and cleaning may be required to ensure accurate observations.
when viewing objects under high-power, the field of view is smaller, but you are able to see more details.
when viewing objects under high-power, the field of view is smaller, but you are able to see more details.
The gravitational field of Earth - or any other object for that matter - gets weaker and weaker at larger distances, but never entirely drops to zero.
when viewing objects under high-power, the field of view is smaller, but you are able to see more details.
when viewing objects under high-power, the field of view is smaller, but you are able to see more details.
When viewing specimens or objects under a microscope, it should be set to a low power first. This allows for a wider field of view that makes an object easier to locate.
When viewing specimens or objects under a microscope, it should be set to a low power first. This allows for a wider field of view that makes an object easier to locate.
Nearer objects appear larger because of the way our brains interpret visual information based on the object's distance from our eyes. When an object is closer, it occupies a larger portion of our field of vision, which leads our brain to perceive it as larger than objects that are farther away. This is known as the concept of perspective.