Features

Fixed Focal Lengths from 3.5 mm to 75 mm
Zoom Lens Covers 18 - 108 mm Focal Lengths
Fast Lenses up to f/0.95
Manual Focus and Aperture Control
Design Formats as Large as 1"
C-Mount Threaded is Compatible with our CCD and CMOS Cameras

Thorlabs' C-Mount Camera Lens offering includes lenses specifically designed for 1/2", 2/3", and 1" format sensors. Additionally, lenses can be used with smaller format sensors than they are designed for, but the image will be cropped, and will thus act like a longer focal length lens (see Crop Factor tab). These lenses are fully compatible with our compact high-resolution CCD and CMOS cameras, as well as many other cameras that feature C-Mount lens mounts and appropriately sized image sensors.

All lenses are fixed focal lengths (primes), aside from the MVL7000 zooming lens. Because of their simplified optical design, prime lenses commonly offer large maximum apertures and superior imaging characteristics. Zoom lenses, on the other hand, offer superior imaging flexibility. All prime lenses, aside from the MVL25, have locking focus and aperture rings.

We also offer High-Magnification Zoom Lenses, which offer magnification factors of 0.07 to 28.

The focal length of a lens determines the field of view of the camera system. The longer the focal length, the narrower the field of view. A general guideline is that a 50 mm lens on a full frame (35 mm) camera offers the same field of view as the human eye. As per the Crop Factor tab, the approximate human eye focal length equivalents for a few sensor formats are as follows:

Sensor Format	Focal Length for Human Eye Approximate Field of View
1/3"	6.9 mm
1/2"	9.2 mm
2/3"	12.7 mm
1"	18.5 mm

Image samples are shown for 1/3" and 1/2" sensor formats. The products are each roughly spaced in 8" (200 mm) increments. The first is a Polaris Mirror Mount on a Ø1" post placed 8" (200 mm) from the post that the camera is mounted on, the next is a balldriver for 1/4"-20 cap screws, third a Ø1.5" post, and lastly an RSP1X15 rotation mount on a Ø1/2" post and base. You will notice with wide angle lenses (short focal lengths), such as the MVL4WA, that the image exhibits barrel distortion. This is readily apparent with the mirror mount on a Ø1" post in the foreground as the post is actually straight.

1/3" Format Sensors

1/2" Format Sensors

MVL4WA: 4 mm Focal Length, 1/2" Format

5.2 mm Adjusted Focal Length
MVL4WA on DCU223C

4 mm Focal Length
MVL4WA on DCU224C

MVL8M23: 8 mm Focal Length, 2/3" Format

14.64 mm Adjusted Focal Length
MVL8M23 on DCU223C

11 mm Adjusted Focal Length
MVL8M23 on DCU224C

MVL16M23: 16 mm Focal Length, 2/3" Format

29.28 mm Adjusted Focal Length
MVL16M23 on DCU223C

22 mm Adjusted Focal Length
MVL16M23 on DCU224C

MVL25M23: 25 mm Focal Length, 2/3" Format

45.75 mm Adjusted Focal Length
MVL25M23 on DCU223C

34.375 mm Adjusted Focal Length
MVL25M23 on DCU224C

MVL35M23: 35 mm Focal Length, 2/3" Format

64.05 mm Adjusted Focal Length
MVL35M23 on DCU223C

48.125 mm Adjusted Focal Length
MVL35M23 on DCU224C

MVL50M23: 50 mm Focal Length, 2/3" Format

91.5 mm Adjusted Focal Length
MVL50M23 on DCU223C

68.75 mm Adjusted Focal Length
MVL50M23 on DCU224C

MVL75L: 75 mm Focal Length, 2/3" Format

137.25 mm Adjusted Focal Length
MVL75L on DCU223C

103.125 mm Adjusted Focal Length
MVL75L on DCU224C

Understanding apertures on camera lenses is important when selecting the appropriate lens for your application. The aperture is a ratio that tells you the amount of light that a lens can collect. The apertures on our C-mount lenses are adjustable to vary the amount of light let in. The more light a lens collects, the shorter the camera exposure needed. Camera lenses that can collect a lot of light are known as fast lenses as they can be used with shorter exposure times. In the specification tables below, the maximum aperture is given for each lens. This is what is important when judging how fast a camera lens is. Aperture is specified as a ratio f/#, such as f/1.4. "f" stands for the focal length of the lens, and thus, the smaller the denominator of this ratio, the more light that can be collected.

In general,
,
where f = focal length and d = aperture diameter (or, if the aperture is not circular, the diameter of a circular aperture with the same area).

Fast lenses are ideal for low-light conditions. For example, a 50 mm focal length lens with f/1.4 aperture has a 35.7 mm (50 mm/1.4) aperture. A slower lens would be a 50 mm lens with a f/2.8 maximum aperture, relating to a maximum aperture size of 17.9 mm (50 mm/2.8). To give a better perspective on what these aperture values mean, let's look at a table of full stop apertures. With each step to a smaller aperture (larger denominator), the light collected by the lens is cut in half.

	Light Collected Decreases
f/#	1	1.4	2	2.8	4	5.6	8	11	16	22	32

While knowing the maximum amount of light a lens can collect is important, there are downsides to using lenses at large apertures. The larger the aperture of the lens, the smaller the in-focus region of the image. This in-focus region is commonly known as the depth of field, meaning the distance between the foremost and backmost objects that are in focus. The images below are taken with the same lens (MVL8L on a 1/2" format camera), but different apertures. The aperture is wide open (f/1.4) in the first image and as small as possible (f/16) in the last image.

f/1.4

f/2

f/2.8

f/4

f/5.6

f/8

f/11

f/16

While camera lenses are designed for a specific sensor format (size), they can be used with other format sensors. Using a larger sensor than the lens is designed for is typically undesirable as the lens is not capable of imaging across the whole sensor. Alternatively, using a smaller sensor is very common. In these cases, a Crop Factor is introduced. This Crop Factor is a ratio of the lens' design format diagonal length divided by the format diagonal length of the sensor used. The table below lists the approximate crop factors that are possible for 1/3", 1/2", 2/3", and 1" format sensors.

Sensor Format Used	Lens Design Format
-	1/3"	1/2"	2/3"	1"
1/3"	1	1.3	1.83	2.67
1/2"	-	1	1.375	2
2/3"	-	-	1	1.45
1"	-	-	-	1

The Crop Factor has a significant effect on the Field of View of each lens. Another term for Crop Factor is Focal Length Multiplier. When using a lens with a smaller format sensor, multiply the Focal Length Multiplier (Crop Factor) by the focal length of the lens. The lens will "feel" like the resulting product. For example, a 50 mm focal length lens designed for a 1" sensor will have the "feel" of a 100 mm focal length lens when used with a 1/2" sensor.

There are two sample images below. Both were photographed with an MVL4WA (f = 4 mm, 1/2" format). The left photograph was taken with a 1/2" format sensor and the right image was taken with a 1/3" format sensor. On the 1/3" format sensor, the 4 mm focal length lens will have a field of view roughly that of a 5.2 mm focal length lens. A table below the images lists the focal lengths "compensated" for 1/3", 1/2", 2/3", and 1" sensor formats.

1/2" Format Sensor

1/3" Format Sensor

MVL4WA: 3.5 mm Focal Length, 1/2" Format

3.5 mm Focal Length
MVL4WA on DCU224C

4.6 mm Adjusted Focal Length
MVL4WA on DCU223C

Item #	Adjusted Focal Lengths for Various Sensor Formats
Item #	1/3"	1/2"	2/3"	1"
MVL4WA	4.6 mm	3.5 mm	-	-
MVL5WA	5.9 mm	4.5 mm	-	-
MVL6WA	7.8 mm	6 mm	-	-
MVL5M23	9.2 mm	6.9 mm	5 mm	-
MVL8M23	14.6 mm	11 mm	8 mm	-
MVL8L	14.6 mm	11 mm	8 mm	-
MVL12WA	15.6 mm	12 mm	-	-
MVL8M1	21.4 mm	16 mm	11.6 mm	8 mm
MVL12M23	22 mm	16.5 mm	12 mm	-
MVL12L	22 mm	16.5 mm	12 mm	-
MVL16M23	29.3 mm	22 mm	16 mm	-
MVL16L	29.3 mm	22 mm	16 mm	-
MVL12M1	32 mm	24 mm	17.4 mm	12 mm
MVL16M1	42.7 mm	32 mm	23.2 mm	16 mm
MVL17HS	45.4 mm	34 mm	24.7 mm	17 mm
MVL25M23	45.8 mm	34.4 mm	25 mm	-
MVL25	45.8 mm	34.4 mm	25 mm	-
MVL35M23	64.1 mm	48.1 mm	35 mm	-
MVL35L	64.1 mm	48.1 mm	35 mm	-
MVL25HS	66.8 mm	50 mm	36.3 mm	25 mm
MVL25M1	66.8 mm	50 mm	36.3 mm	25 mm
MVL50M23	91.5 mm	68.8 mm	50 mm	-
MVL50L	91.5 mm	68.8 mm	50 mm	-
MVL35M1	93.5 mm	70 mm	50.8 mm	35 mm
MVL50HS	133.5 mm	100 mm	72.5 mm	50 mm
MVL50M1	133.5 mm	100 mm	72.5 mm	50 mm
MVL75L	137.3 mm	103.1 mm	75 mm	-
MVL75M1	200.3 mm	150 mm	108.8 mm	75 mm

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Posted Comments:

Poster: dgardner

Posted Date: 2012-05-09 10:08:00.0

Response from Dave at Thorlabs: Thank you for your question. Your Thorlabs CCD camera is fully compatible with the MVL7000 Zoom Lens, as both feature a C-Mount lens mount. Please note that since the MVL7000 is designed for a 2/3" sensor, a crop factor will be present. Refer to the Specs table in the MVL7000 desicrption for details. Your CCD camera is also compatible with Thorlabs' SM1 lens tube threading, via the included C-Mount to internal SM1 and C-Mount to external SM1 adapters. Please contact techsupport@thorlabs.com if you have any further questions.

Poster: carlos.jarro

Posted Date: 2012-05-08 15:58:13.0

Hello, I already have a CCD camera which comes with a plastic case. Now I am really needing the MVL7000 zoom lens. You recommend "additional hardware" to mount the camera/lens in your web page. What is the recommended hardware to mount the camera/lens on a cage system?

Poster: bdada

Posted Date: 2012-03-15 11:49:00.0

Response from Buki at Thorlabs to gilad: Thank you for your feedback. We are working on getting the MTF curves and will post an update here when we get it.

Poster: gilad

Posted Date: 2012-03-12 11:02:56.0

Must have MTF for all the lens in order to see if it is good enough.

Poster: bdada

Posted Date: 2011-10-31 18:28:00.0

Response from Buki at Thorlabs: Thank you for your feedback. The objective is coated and we will send you a graph that shows the transmission of the objective from 400nm to 1000nm. We will also update our web presentation to include more information. Please contact TechSupport@thorlabs.com if you have further questions.

Poster: otni

Posted Date: 2011-10-31 06:05:28.0

I am constructing a vision system for hyperspectral imaging, and need an objective that can cover the spectral range from ~450 nm - 1050 nm. But i have not found any description of the coating for your lenses. Can you supply me with this, or tell me how to retrieve it myself? Kind regards -Otto Nielsen

Poster: Thorlabs

Posted Date: 2010-07-14 09:28:06.0

Response from Javier at Thorlabs to steffen.kalfhues: thank you for your feedback. The transmission for the MVL25 camera lens is ~40% in the 340-350 nm range. We currently do not offer lenses specifically designed for use in the UV spectrum.

Poster: steffen.kalfhues

Posted Date: 2010-07-14 01:49:21.0

Hi, what will the transmission of the MVL25 @ 343nm be? Do you offer lenses for explicit use with UV? Thx

Poster: Javier

Posted Date: 2010-06-16 10:15:33.0

Response from Javier at Thorlabs to mskiba: you can use our SM1A10 and SM1A9 adapters, along with an SM1 lens tube, to reduce the focusing distance of your lens. I will contact you directly with links for these parts.

Poster: mskiba

Posted Date: 2010-06-16 05:46:00.0

Do you offer an accesory to reduce minimum focusing distance (i.e. extension tube)? Thanks

Poster: Adam

Posted Date: 2010-05-27 17:34:42.0

A response from Adam at Thorlabs to Ron: The transmission of the MVL25 at 365nm is ~40%.

Poster: ron

Posted Date: 2010-05-27 13:04:12.0

Whats the performance of the MVL25 lens at 365 nm?

Poster: apalmentieri

Posted Date: 2010-02-24 16:18:33.0

A response from Adam at Thorlabs to Mtrigo: The DCC1545M CMOS camera comes with CS-C mount adapter so you will not need to purchase extra components.

Poster: mtrigo

Posted Date: 2010-02-24 15:38:58.0

which mounting adapter do I need to use the zoom lens MVL74L with a DCC1545M CMOS camera? I dont think this is clear from the website

Poster: apalmentieri

Posted Date: 2010-02-08 15:17:03.0

A response from Adam at Thorlabs to Soia: The spectral transmittance of our lenses found on this website are 400-1000nm with a %T>90%. The cameras we offer are based off of silicon technology and would detect light from 400-1100nm(Monochrome only), but the color camera versions have IR filters that filter out the IR light so they would only detect light from 400-700nm. I will email you directly to find out which camera you are referencing so we can provide more accurate data.

Poster: soia_1_is

Posted Date: 2010-02-07 01:56:09.0

I would like to know what is the spectral transmittance of these cameras and lenses. Too bad the data is not available in the specs. Jonathan

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