Understanding a manufacturer’s specifications for a lens can greatly simplify the research and purchasing processes. In order to know how a lens works, it is critical to understand resolution, magnification, contrast, f/#, and how to read common performance curves including Modulation Transfer Function (MTF), Depth of Field (DOF), Relative Illumination, and distortion.
Resolution is a measurement of an imaging
system’s ability to reproduce object detail, and can be influenced by
factors such as the type of lighting used, the pixel size of the sensor,
or the capabilities of the optics. The smaller the object detail, the
higher the required resolution.
Dividing the number of horizontal or vertical
pixels on a sensor into the size of the object one wishes to observe
will indicate how much space each pixel covers on the object and can be
used to estimate resolution. However, this does not truly determine if
the information on the pixel is distinguishable from the information on
any other pixel.
As a starting point, it is important to
understand what can actually limit system resolution. An example can be
shown in Figure 1 a pair of squares on a white background. If the
squares are imaged onto neighboring pixels on the camera sensor, then
they will appear to be one larger rectangle in the image (1a) rather
than two separate squares (1b). In order to distinguish the squares, a
certain amount of space is needed between them, at least one pixel. This
minimum distance is the limiting resolution of the system. The absolute
limitation is defined by the size of the pixels on the sensor as well
as the number of pixels on the sensor.
The Line Pair and Sensor Limitations
The relationship between alternating black and
white squares is often described as a line pair. Typically, the
resolution is defined by the frequency measured in line pairs per
millimeter (lp/mm). A lens’s resolution is unfortunately not an absolute
number. At a given resolution, the ability to see the two squares as
separate entities will be dependent on grey scale level. The bigger the
separation in the grey scale between the squares and space between them
(Figure 1b), the more robust is the ability to resolve the squares. This
grey scale separation is known as contrast (at a specified frequency).
The spatial frequency is given in lp/mm. For this reason, calculating
resolution in terms of lp/mm is extremely useful when comparing lenses
and for determining the best choice for given sensors and applications.
The sensor is where the system resolution calculation
begins. By starting with the sensor, it is easier to determine what
lens performance is required to match the sensor or other application
requirements. The highest frequency which can be resolved by a sensor,
the Nyquist frequency, is effectively two pixels or one line pair. Table
1 shows the Nyquist limit associated with pixel sizes found on some
highly used sensors. The resolution of the sensor, also referred to as
the image space resolution for the system, can be calculated by
multiplying the pixel size in μm by 2 (to create a pair), and dividing
that into 1000 to convert to mm:
Sensors with larger pixels will have lower limiting
resolutions. Sensors with smaller pixels will have higher limiting
resolutions.
With this information, the limiting resolution on the
object to be viewed can be calculated. In order to do so, the
relationships between the sensor size, the field of view, and the number
of pixels on the sensor need to be understood.
Sensor size refers to the size of a camera sensor’s
active area, typically specified by the sensor format size. However, the
exact sensor proportions will vary depending on the aspect ratio, and
the nominal sensor formats should be used only as a guideline,
especially for telecentric lenses and high magnification objectives. The
sensor size can be directly calculated from the pixel size and the
number of active pixels on the sensor.
To Know More About To Know More About Edmund Optics Imaging Lenses in India , Contact Menzel Vision and Robotics Pvt Ltd at (+ 91) 22 67993158 or Email us at info@mvrpl.com
Contact Details
Address: 4, A-Wing, Bezzola Complex,
Sion Trombay Road, Chembur
400071 Mumbai, India
Tel:(+91) 22 67993158
Fax: (+91) 22 67993159
Mobile:+91 9323786005 / 9820143131
E-mail: info@mvrpl.com
Sion Trombay Road, Chembur
400071 Mumbai, India
Tel:(+91) 22 67993158
Fax: (+91) 22 67993159
Mobile:+91 9323786005 / 9820143131
E-mail: info@mvrpl.com
Source - edmundoptics.com
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