Description

Lightguide collimators are used to either couple light from free space into a lightguide or collimate light from a lightguide to form a collimated (parallel) optical beam. Lightguide collimators are key components with numerous applications. For example, a lightguide collimator can project light from a lightguide into a uniform spot in free space.

High-numerical-aperture aspherical lenses are used for precise collimation and maximum light throughput. The collimator features adjustable focus from ~100mm to infinity. Various lightguide ferrule diameters are supported. Customization is available for other ferrule diameters.

The full field of view (FOV) or full divergence angle can be calculated as FOV = 2atan(D/2f), where D is the lightguide core diameter and f is the focal length of the lens. Alternatively, the linear field of view on an object placed at a distance L away from the collimator is D(L/f).

Lightguide collimator with lightguide and GCS source

Features:

Aspherical lens
Adjustable focus with locking ring
Accepts various ferrule diameters

Applications:

Coupling light into lightguides
Collimating light from lightguides

Specifications

Part Number	Focal Length (mm)	Clear Aperture (mm)	F# / NA	Lens Material	Wavelength Range (nm)	Lightguide Ferrule OD¹
LGC-019-022-05-V	19	22	0.86/0.5	B270	350 ~ 2,000	5 mm
LGC-019-022-07-V	19	22	0.86/0.5	B270	350 ~ 2,000	7 mm

1. Ferrule length must be at least 15 mm.

Data Sheet:

Lightguide collimator data sheet (.pdf file, 506 kB, at manufacturer's website )

Installation Drawings:

Installation drawing for LGC-019-022-05-V (.pdf file, 38 kB, at manufacturer's website)
Installation drawing for LGC-019-022-07-V (.pdf file, 38 kB, at manufacturer's website)

IMPORTANT : (1) LED’s can ONLY be driven by a constant-current source, and NOT a voltage source (e.g. a battery, or a AC/DC power supply etc.); (2) Please always verify LED’s current rating first before applying current to the LED, and please always make sure NOT to apply current that is above the LED’s current rating.

About Mightex High Power LED Light Sources

Selecting a Microscopy LED Light Source

1. Select LED Wavelength

Emission Spectra — Multiple Available Wavelengths (Click to enlarge. Also see: Specification Sheet; Manufacturer's website)

2. Select LED Configuration

Mightex Microscope LED Light Source Configuration — Single-Wavelength: **Type A, Type B, Type J & Type H**

3. Select LED Controller

Mightex Microscope LED Light Source Controller Option — Manual/Analog: BLS-1000-2, BLS-3000-2, BLS-13000-1, and BLS-18000-1

4. Microscope Coupling

Microscope adapters are available for all major manufacturers (Nikon, Olympus, Leica, Zeiss). If you have a different microscope, please contact us.

LED Application Examples

Abdelfattah AS et al., Bright and Photostable Chemigenetic Indicators for Extended In Vivo Voltage Imaging – Science (2019)
Abdelfattah et al., developed novel chemigenetic indicators for in vivo voltage imaging in neurons. To illuminate their indicators, the group used Mightex’s Microscope LEDs.

Crandall SR, et al., Infrabarrels Are Layer 6 Circuit Modules in the Barrel Cortex that Link Long-Range Inputs and Outputs – Cell Reports (2017)
In this work, Crandall et al., used Mightex’s Microscope LEDs to optically stimulating different neuronal pathways connecting to pyramidal neurons found in L6 of the whisker somatosensory cortex of mice.

Higgs MH, Measurement of Phase Resetting Curves Using Optogenetic Barrage Stimuli – Journal of Neuroscience Methods (2017)
To study phase resetting curves in vivo, Higgs and Wilson used Mightex’s Microscope LEDs to establish whether their novel method of optogenetic barrage stimulation would work during extracellular spike recordings (a recording method often used in in vivo experiments).