The low power objective allows you to see the largest area of the specimen you are viewing. It typically has a magnification of 10x.
With a 4x objective lens compared to a 40x objective lens, you would see a larger area of the specimen, but the image would be less detailed and magnified with the 4x objective. The 40x objective would provide a much closer and higher magnification view of a smaller area of the specimen.
The high power objective on a microscope increases the magnification of the specimen, which allows you to see more detail. It allows you to see a close up of only a small area of the specimen being viewed.
Specimen orientation on a microscope refers to the position and alignment of the specimen on the microscope stage. Correct orientation is important to ensure that the desired area of the specimen is visible and in focus under the microscope objective lens. Properly orienting the specimen allows for accurate observation and analysis of its features.
As you increase the magnification of the objective lens, the light intensity reaching the specimen decreases. This is due to the fact that the same amount of light is spread out over a larger area with higher magnification, resulting in lower intensity at the specimen.
Centering your specimen under the lowest objective lens ensures that the area of interest is in the field of view when you switch to a higher magnification. This minimizes the risk of losing the target area and allows for a smoother transition between objectives. Additionally, it helps maintain proper focus and avoids potential damage to the slide or the lens when adjusting for higher magnifications.
Centering the specimen before switching to high power helps ensure that you are viewing the area of interest in focus. It helps prevent the objective lens from hitting the slide, which can damage both the lens and the specimen. Additionally, centering the specimen can improve the image quality by reducing glare and shadowing.
The low power objective is used first for two reasons: First, focusing the low power objective will insure that the other objectives will be at the proper height. Smashing a slide with an objective can damage the objective. Second, you can see a greater area with the low powered objective. This allows you to easily locate an object of interest, center it in frame and then zoom in on it.
When observing a specimen under a microscope, you typically start with a low magnification objective, such as 4x or 10x, to locate and identify the targets of interest. Once you have identified the general area of interest, you can then switch to higher magnification objectives, such as 40x or 100x, for more detailed observation and analysis.
You go to the battle area and survival area and fight everyone there. Your biggest objective next is catch all Pokemon from all games
When an objective lens in a light-path objective (LPO) microscope is shifted from the Low Power Objective (LPO) to the High Power Objective (HPO), the image becomes magnified and the field of view decreases. This results in higher magnification but a smaller area of the specimen being visible at once.
Going to high power on a microscope decreases the area of the field of view. The field of view is inversely proportional to the magnification of the objective lens. ... The specimen appears larger with a higher magnification because a smaller area of the object is spread out to cover the field of view of your eye