OP Mount Instrument Catalog K13

Optical Tables P MMTRW MTRWHStages Motion Control Rotary StagesOptical Mounts Specifications Drive Type: Stepping MotorComponents Motion Systems Education Systems Weight 1.1 ~ 3.2 kg Loading 10 ~ 50 kgLasers Resolution : 0.0025° / 0.00125° Repeatability : ±0.0025° / ±0.00125°Optics & Crystals Other Equipment Surface Parallelism: ±0.0025° / ±0.00125° High accuracy and loading Customized specifications upon request Metric / Imperial Version available To order Imperial model please add *I-* to item Specification & Item Numbers MR- 66 MR-66 MRH- 46 MRH-46E. 35 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

P TEL 886-3-4397556 FAX 886-3-4398379 http://www.opmount.com.tw @ [email protected] MRH-100 Optical TablesMRH-100 Stages MRH-160 Education Systems Motion Systems Components Optical MountsMRH-160 MRH-200MRH-200 LarersItem Number Platfrom Load Resolution Repeatability Straightness Weight Other Equipment Optics & Crystals Ø (mm) Capacity (°) ±(°) Parallelism (kg)MR-66 66 (2.6”) 1.2MRH-46 (kg) 0.0025 0.0025 ±(mm) 0.43MRH-100 46 (1.81”) 10 0.02 2.5MRH-160 100 (3.94”) 0.0025 0.0025 7MRH-200 160 (6.3”) 5 0.00125 0.00125 0.02 11.2 200 (7.9”) 0.00125 0.00125 15 0.00125 0.00125 0.02 bOP 20 0.25 30 0.25 www.opmount.com.tw E. 36

Production Line F F Education SystemsOptical Tables Products Categories 1(: New Products %(67 Best SellerStages AOptical Mounts (GXFDWLRQ (G6X\VFWDHWPLRVQComponents Motion Systems Education Systems 6\VWHPVLasers F. 03 Modern Experimental OpticsOptics & Crystals Other Equipment F. 04 Basics of Experimental Optics ------- EDB-01 %(67 F. 05 Snell's Law Reflection and Refraction ------- EDB-02F. 01 AF. 06 Polarization of Light ------- EDB-03 %(67 F. 07 Lens Aberration ------- EDB-04 F. 08 Thin-lens Imaging ------- EDB-05 F. 09 Michelson / Mach-Zehnder / Sagnac Interferometers ------- EDB-06 F. 10 Etalon Interference ------- EDB-07 %(67 F. 11 Coherence Theory of Light ------- EDB-08 F. 12 Diffraction ------- EDB-09 %(67 F. 13 Grating Monochromater ------- EDB-10 %(67 F. 14 Principle of Optical Waveguides ------- EDB-11 %(67 F. 15 Fourier Optical Education System ------- EDB-12 %(67 EF. 16 Electro-Optic Modulation ------- EDC-01 Production Line F - Education Systems

FC. A B C D E F G H I Optical Tables C. Optical Tables F. 16 Acousto-Optic Modulation ------- EDC-02 Stages F. 17 Noncritically Phase-Matched Second Education Systems Motion Systems Components Optical Mounts Harmonic Generation ------- EDC-03 F. 17 Quasi Phase-Matched Nonlinear Wavelength Larers Conversion ------- EDC-04 Other Equipment Optics & Crystals F. 18 Optical Parametric Generation ------- EDC-05 Optics & Crystals F. 18 Stimulated Raman Scattering ------- EDC-06 F. 19 Probe Station Module F. 20 Multi-Measurement Method The characteristic of education experiment module :Complete optic education experiemnt course for an academic yearEach experiement can stand alone for operation simultaneouslyThe experiment would be described very detail by operation manualEnglish or Chinese version availableOP Mount technology supporting team provides total solution service foreducation usersThe technology for education experiment of OP Mount Instrument Inc. istransferred by National Tsing Hua University in TaiwanThe product is convenient for operation and improved for optimum by OPMount Instrument Inc Production Line F - Education Systems F. 02

P Modern Experimental OpticsOptical TablesStagesOptical MountsComponents Motion Systems Education Systems 1 Beginner's Optics Module 2 Snell's Law Reflection and RefractionLasers 3 Polarization of Light 4 Lens AberrationOptics & Crystals Other Equipment 5 Thin-lens Imaging 6 Michelson / Mach-Zehnder / Sagnac Interferometers 7 Etalon Interference 8 Coherence Theory of Light 9 Diffraction 10 Grating Monochromater 11 Principle of Optical Waveguides 12 Fourier Optical Education System 13 Electro-Optic Amplitude Modulation 14 Acousto-Optic Modulation 15 Non-critically Phase-Matched Second Harmonic Generation 16 Quasi Phase-Matched nonlinear wavelength conversion 17 Optical Parametric Generation 18 Raman ScatteringF. 03 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

EDB P -01Basics of Experimental Optics Optical Tables Stages Application Education Systems Motion Systems Components Optical Mounts Lens / Mirror Cleaning Laser Alignment Larers Purpose of the Experiment Other Equipment Optics & CrystalsThe design of this basic experiment is to assist a novice in optics to get familiar withhandling optical components and aligning an optical path. The experience learned fromthis experiment is also helpful to stay alert for laser safety and avoid damaging opticalcomponents. Lens / Mirror CleaningThis part of experiment teaches the proper way of cleaning lenses and mirrors by usinglens papers and several solvents. Laser AlignmentThis experiment is divided into two parts. The first part of the experiment is to align ared laser beam into two longitudinally separated apertures by using two orthogonally tunedmirrors. The second part of the experiment is to co-propagate a green laser with thepre-aligned red laser beam. If an optical material is cut into a prism shape, the dispersion of the material can bedetermined with great accuracy by measuring the minimum deflection angle of the prismover a spectral range. This experiment demonstrates such a refractive index measurementtechnique.www.opmount.com.tw bOP F. 04

P QE-0DM2BT Snell’s Law Reflection and RefractionOptical TablesStagesOptical MountsComponents Motion Systems Education Systems ApplicationLasers Snell's Law Reflection and Refraction Minimum Deflection Angle of a PrismOptics & Crystals Other Equipment Total Internal Reflection Purpose of the Experiment This experiment demonstrates Snell's law of refraction and reflection, from which one measures the refractive index of a material. Saell’s Law of Reflection A fixed laser beam is incident on a rotating mirror and the scanning angle of the reflection beam. Also, it is twice the rotation angle of the mirror. Total lnternal Reflection A laser beam is directed into the center of an acrylic half-cylinder atop a rotation stage. One confirms Snell¡¦s law of reflection and refraction from the angles of the incident, reflected, and transmitted beams. When the incident angle is larger than the critical angle, total internal reflection in the acrylic cylinder occurs.F. 05 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

EDB P -03Polarization of Light Optical Tables Stages Application Education Systems Motion Systems Components Optical Mounts Malus's Law Larers Polarization Control Using Polarizer and Waveplate Brewster Angle Other Equipment Optics & Crystals Purpose of the ExperimentThis experiment illustrates the polarization of light, the use of waveplates for polarizationcontrol, and the polarization-dependent reflection of light from a material. Description of the ExperimentThis experiment starts with the investigation of Malus's law, which states thattransmittance of a linear polarized light through a polarizer is the square of a cosine of therelative angle between the polarization direction and the transmission axis of the polarizer.In the second part of the experiment, one employs a half-wave plate to rotate thepolarization direction of a linearly polarized laser beam and a quarter-wave plate toproduce elliptically and circularly polarized light. The transmission and reflection of lightfrom a material depends on the polarization of the incident light. In this experiment, onemeasures the intensity of reflected light from a glass material upon which a p- ors-polarized laser is incident. From the measured data, the Brewster angle of a p-polarizedincident laser on a glass can be determined. www.opmount.com.tw bOP F. 06

QEQ-0DMM4BTT Lens AberrationOptical TablesStagesOptical MountsComponents Motion Systems Education Systems ApplicationLasers Spherical Aberration, Coma, AstigmatismOptics & Crystals Other Equipment Purpose of the Experiment Observation of those aberrations associated with a spherical lens, including spherical aberration, coma, and astigmatism. Description of the Experiment The spherical aberration experiment employs a large aperture spherical lens following a slide with transparent dots at different radial distances. An expanded, collimated laser beam is incident on the slide and the large-aperture lens to illustrate variation of focal points from light rays emitting from radial positions. The second experiment shows a typical coma pattern by imaging an off axis point source through a lens following a slide with concentric transparent rings. The third experiment is to illustrate astigmatism of a spherical lens, which allows the measurement of the circle of least confusion between two focused lines formed by the tangential rays and the sagittal rays through a rotated lens.F. 07 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

EDB -05Thin-lens lmaging Optical Tables StagesApplication Education Systems Motion Systems Components Optical MountsKnife-edge Focal-length Measurement Laser-Beam ExpansionSingle-lens Imaging Two-lens SystemPurpose of the ExperimentThe primary purpose of this experiment is to teach the principle of a single imaging lensand a multi-lens imaging system. This experiment also teaches the basic skills of creatingan expanded and collimated laser beam, and measuring the focal length of a lens by usingthe knife-edge technique. Description of the Experiment LarersLaser beam expansion:This technique is often needed in optics experiments. In this Other Equipment Optics & Crystalsexperiment, we use a negative lens and a positive lens to form a confocal telescopicsystem. Expansion ratios of different focal-length combinations are verified in theexperiment.The knife-edge technique is a classic means for measuring the focal length of a lens. Aunique knife-edge assembly is designed for measuring the focal lengths of several positivelenses.Single-lens imaging: This part of the experiment verifies the imaging formula of a thin lens.Measurement of the focal length of a negative lens: This part of experiment isaccomplished by imaging the virtual image formed by the negative lens through a positivelens with a known focal length. The focal length of a negative lens is deduced fromsuccessive uses of the single-lens imaging formula. www.opmount.com.tw bOP F. 08

P EDB -06 Michelson / Mach-Zehnder / Sagnac InterferometersOptical TablesStagesOptical MountsComponents Motion Systems Education Systems ApplicationLasers Minimum deflection angle of a prism Total internal reflectionOptics & Crystals Other Equipment Mach Zhender Interferometer Purpose of the Experiment This experiment demonstrates Snell's law of refraction and reflection, from which one measures the refractive index of a material. Total Internal Reflection This experiment teaches step-by-step procedures for setting up a Mach Zhender interferometer, a Sagnac Interferometer, and a Michelson interferometer. To obtain clear concentric interference patterns at the output, the wavefront of the optical wave in one interferometer arm is deliberately adjusted differently from that in the other interferometer arm. A Mach Zhender interferometer is used to demonstrate complimentary interferometer patterns at its two output ports. As a common-path interferometer, a Sagnac interferometer is used to illustrate a much stable interference fringes compared with those from the other two interferometers. In the end, a glass plate is inserted into a Michelson interferometer and a Mach Zhender interferometer for precise refractive index measurements.F. 09 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

EDB P -07Etalon Interference Optical Tables StagesApplication Education Systems Motion Systems Components Optical MountsRefractive index Measurement Using Etalon Finesse MeasurementEtalon FringesPurpose of the ExperimentThis experiment teaches basic principles of optical interference and resonance bycharacterizing the interference fringes and finesse of an etalon. What to be learn from thisexperiment includes the concept of free spectral range, Fabry-Perot resonator, resonatorbandwidth, and spectral selection. Description of the Experiment LarersThis experiment is divided into two parts; the first part is to illustrate the interference Other Equipment Optics & Crystalsfringes from an Etalon and the second part is to measure an Etalon's finesse.Part I. Etalon Interference FringesA diffused He-Ne laser beam is incident on an Etalon followed by a focusing lens. On thefocal plane, one observes and characterized an interference pattern with concentric rings.The refractive index and thickness of the Etalon are correlated with the experimental data.Part II. Etalon Finesse MeasurementEtalon finesse is an important index for spectral selectivity. In this experiment, a collimatedHe-Ne laser beam is incident on a spinning Etalon. From the oscilloscope trace of thetransmitted laser intensity, an Etalon’s free spectral range and finesse are deduced. www.opmount.com.tw bOP F. 10

Optical Tables P QE-0DM8BTStages Coherence Theory of LightOptical Mounts Application Minimum deflection angle of a prismComponents Motion Systems Education Systems Diode-Laser Coherence Length LED Coherence Length White-Light Interference Purpose of the Experiment Optical coherence manifests itself in optical interference. This experiment teaches the temporal coherence of light waves by observing time-shift interference fringes of several light sources in a Michelson interferometer.LasersOptics & Crystals Other EquipmentF. 11 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

EDB P -09Diffraction Optical Tables Stages Application Education Systems Motion Systems Components Optical Mounts Fresnel Diffraction Larers Fraunhofer Diffraction Other Equipment Optics & Crystals Purpose of the ExperimentOptical diffraction is a classical test on the wave-like nature of light. This experimentteaches Fresnel diffraction, of which the diffraction pattern is influenced by the wavefrontat the diffraction aperture, and Fraunhofer diffraction, of which a plane-wave model is usedat the diffraction aperture and the observation screen. Description of the ExperimentFresnel Diffraction,a quasi point wave is first generated from a strongly focused laserbeam and then is incident on circular apertures of different radii. By varying the distancebetween the aperture and the point source, one is able to observe several diffractionorders of the Fresnel diffraction on a fixed screen. With different-radius apertures in theexperiment, an experimenter is able to learn the importance of a spherical wavefront ingenerating Fresnel diffraction.Fraunhofer diffraction is a kind of far-field diffraction and its diffraction pattern is the Fouriertransform of the diffraction aperture. A series of circular and rectangular apertures areused in this experiment to verify the far-field diffraction theory. The dimensions of theapertures are deduced from the measured diffraction patterns. www.opmount.com.tw bOP F. 12

P QE-1DM0BT Grating MonochromaterOptical TablesStagesOptical MountsComponents Motion Systems Education Systems ApplicationLasers Grating-Period Measurement Grating MonochrometerOptics & Crystals Other Equipment Purpose of the Experiment An optical grating is an optically dispersive element and is often used for spectral measurements or dispersion processing of optical waves. This experiment teaches the basic principle of optical diffraction from a grating and the functioning principle of a grating monochrometer. Total lnternal Reflection This first part of the experiment employs a laser of a known wavelength to observe diffraction orders from an optical grating. From the incidence and diffraction angles of the laser beam, one can deduce the period of the optical grating from the grating equation. The second part of the experiment utilizes the optical grating measured in the first experiment to construct a Littrow grating monochrometer. The spectral lines of a mercury lamp are identified in the monochrometer with a specified resolution.F. 13 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

EDB P -11Principle of Optical Waveguides Optical Tables Stages Application Education Systems Motion Systems Components Optical Mounts Numerical Aperture of a Waveguide Larers Waveguide-Loss Measurement Fiber-Mode Observation Other Equipment Optics & Crystals Purpose of the ExperimentOptical waveguides are widely used in optical signal processing and transmission. Themost notable application of an optical waveguide is the fiber communication. Thisexperiment teaches basic properties of an optical waveguide, including the numericalaperture, optical coupling, waveguide attenuation, waveguide modes, and so on. Description of the ExperimentThe first part of the experiment is the measurement of the numerical aperture of a planarwaveguide. One determines the numerical aperture of the waveguide by observing thesudden loss of the optical beam when increasing the incidence of a laser beam.The second part of the experiment is the measurement of optical coupling loss at andoptical attenuation in a optical fiber. Through this experiment, one also practices couplinga laser beam into an optical fiber.The third part of this experiment is to observe and select waveguide modes in an opticalfiber. The mode selection is achieved by using a mode attenuator.www.opmount.com.tw bOP F. 14

P QE-1DM2BT Fourier Optical Education systemOptical TablesStagesOptical Mounts D BCComponents Motion Systems Education Systems Purpose of the ExperimentLasers How does the discussion object spatial frequency and use it to control the imagery the quality with the shape.Optics & Crystals Other Equipment Carries on simple optics image processing using the Fourier optics theory. Total lnternal Reflection This experiment discusses how is the subject and object spatial frequency are, and uses it to control the imagery, shape and quality. This subject seeks a specific profile, the harmonic frequency is the same concept in the Fourier optics theory mentioned that object all has the specific intensity pattern and may transform for the relative spatial frequency distribution. In this experiment laser is shone by the thunder the object slide. Transforms the lens, the affiliation by hereafter to inspect its spatial frequency the distribution In transforms the lens in the focal-plane to present. The affiliation by holds controls in this focal-plane the light We then may control the imagery the content and the quality.F. 15 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

EDC EDC P -01 -02Electro-Optic Modulation Acousto-Optic Modulation Purpose Optical TablesThe purpose of this experiment is to learn about Electro-Optic Modulation. In this Stagesexperiment we will measure the half-wave voltage of a transverse amplitude modulatormade from a 1-mm-thick LiNbO3 crystal, and find out the modulation depth of the Education Systems Motion Systems Components Optical Mountsmodulated signal. Important Goals of This Experiment To learn the basic concept of the Electro-Optic (Pockels) effect To learn how to determine the transmitting axis of a polarizer To measure the half-wave voltage of the Electro-Optic modulator To modulate the laser beam by using the Electro-Optic modulator at a ~kHz frequency and measure the modulation depth at different frequencies. To observe 2-f modulation and its modulation depth. ApplicationCommunication, LCD display, Phase/intensity modulation, Gas sensing, Laser poweradjuster, Polarization controller, etc. Purpose LarersThis project illustrates spatial light modulation using an Acousto-Optic modulator. Other Equipment Optics & CrystalsExperimentalists will be able to observe different laser diffraction angles and efficienciesas a function of acoustic frequency, intensity, and laser wavelength. Through thisexperiment, one understands acousto-optics as the functioning principle of a spatial lightmodulator. Important Goals of This Experiment To find the Bragg angle versus acoustic frequency. To observe multiple diffraction orders in the Raman-Nath regime. To determine the figure of merit of an Acousto-Optic crystal from experimental data. ApplicationCommunication, LCD display, Phase/intensity modulation, Gas sensing, Laser poweradjuster, Polarization controller, etc. www.opmount.com.tw bOP F. 16

P QE-0DM3CT EDC -04 Noncritically Phase-Matched Quasi Phase-Matched Nonlinear Second Harmonic Generation Wavelength ConversionOptical Tables PurposeStages In this experiment, we will conduct second harmonic generation (SHG) of a 1064-nm Nd:YAG laser in a MgO:LiNbO3 crystal with a Non-critically Phase-Matched configuration.Optical Mounts The temperature tuning curve and the conversion efficiency of the SHG process are to be measured. Students will learn the basic theory of nonlinear optics during the experiment.Components Motion Systems Education Systems Important Goals of This Experiment To learn the basic concept of birefringence phase-matching condition in a nonlinear optical process. To measure the temperature tuning curve of the Noncritical Phase-Matched SHG. To measure the nonlinear conversion efficiency and determine the nonlinear optical coefficient of the MgO:LiNbO3 crystal. To observe the polarization characteristics of the fundamental and the SHG waves. Application Communication, Laser pick-up head, Frequency doubler, etc.Lasers PurposeOptics & Crystals Other Equipment In this experiment, we will be demonstrating the Quasi-Phase-Matched (QPM) second harmonic generation (SHG) in a LiNbO3 crystal, whose ferroelectric domain is periodically reversed every coherence length. Such a LiNbO3 crystal is so-called Periodically Poled Lithium Niobate (PPLN). We will access the first and the third order QPM phase-matching condition and measure the temperature bandwidth of the QPM SHG process. Important Goals of This Experiment To learn the basic concept of QPM phase-matching condition. To measure the temperature tuning curve of the QPM SHG. To measure the nonlinear conversion efficiency and determine the nonlinear optical coefficient of the PPLN crystal. To observe the polarization characteristics of the fundamental and the SHG waves. To know the importance of the grating period of the PPLN crystal. Application Communication, LCD display, Phase/intensity modulation, Gas sensing, Laser power adjuster, Polarization controller, etc.F. 17 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

EDC EDC P -05 -06Optical StimulatedParametric Generation Raman Scattering Purpose Optical TablesOptical Parametric Generation is an important process for producing wavelength Stagestunable coherent radiations. Education Systems Motion Systems Components Optical MountsOptical parametric generation is actually a parametric amplification process in whichvacuum noise photons are amplified to a power levelcomparable to the pump power.In this experiment, we will be performing optical parametric generation (OPG) from a1064-nm pumped Periodically Poled Lithium Niobate (PPLN) crystal.We will measure the wavelength-tuning curve of the OPG outputs for differenttemperatures and/or different PPLN periods in comparison with the theoretical Tuningcurve. Purpose LarersRaman scattering is a useful technique for spectroscopy, wavelength conversion and for Other Equipment Optics & Crystalsoptical signal amplification.Raman scattering is an inelastic scattering process in which a scattering photon loses anddeposits some energy to a host material and the scattered photon has a photon energydifferent from the scattering one.The purpose of this experiment is to achieve stimulated Raman scattering in a silica fiberand measure the Raman gain of a silica fiber.The pump laser is a 1064-nm passive Q-switch laser. www.opmount.com.tw bOP F. 18

P Probe Station ModuleOptical Tables Basic-BPVN-00 IncludingStages Microscope / XY stage (Manual) / XYZ Probe Station / 4 inch vacuum sucker / Magnetic base/Probe Station Board / binocular microscope / Machine BoardOptical Mounts Optional Active Optical table/ Probe Module Isolation Box / Vacuum Pump / Temperature- controlledComponents Motion Systems Education Systems Vacuum Sucker / Cold water machine / Optical fiber / Any kind of measurable sample clamp / Any type of cable adapter (Triaxial to Triaxial, Triaxial to Coaxial, Coaxial to Coaxial) Application LED Wavelength Measurement / LED Light Intensity Measurement / Laser Diode Measurement /Photo Diode Measurement / IC Measurement / Circuit Board Measurement Advanced 4 inch Including -BPVN-02 Microscope / XY Stage(can change to motorized control)  = 6WDJHFDQ FKDQJH WR PRWRUL]HG FRQWURO  șD[LV URWDU\ stage / XYZ Probe Station / 4 inch(8 inch) vacuum sucker / Probe Station Board / Microscope + CCD / CCTV System / Machine Board / Measurement Software / Measurement Instrument (Keithley Model 2400) / Probe Module (Triaxial , Coaxial)LasersOptics & Crystals Other Equipment Optional Z axis Stage( Manual) / Measurement Software / Measurement Instrument (Keithley Model 2400) / Active Optical Table / Probe Module Isolation Box / CCVT System / Vacuum Pump / Temperature - controlled Vacuum Sucker / Cold water machine / Any kind of measurable sample clamp / Any type of cable adapter (Triaxial to Triaxial, Triaxial to Coaxial, Coaxial to Coaxial) Application LED Wavelength Measurement / LED Light Intensity Measurement / Laser Diode Measurement /Photo Diode Measurement / IC Measurement / Circuit Board MeasurementF. 19 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

PMulti-Measurement Method1 Scanning Measurement 2 Fixed Measurement Optical Tables Stages3 Pulse Measurement 4 Customize Measurement Education Systems Motion Systems Components Optical Mounts5 Resistance Measurement 6 Spectrum Measurement Larers Other Equipment Optics & Crystals www.opmount.com.tw bOP F. 20

Production Line G G LasersOptical Tables Products Categories 1(: New Products %(67 Best SellerStages /DVHUVOptical Mounts H. 03 Green Laser Modules H. 13 Sigle Longitudinal Mode Green DPSS LaserComponents Motion Systems Education Systems H. 14 Blue DPSS Laser-Civea473L H. 15 Blue DPSS Laser-Civea473MLasers H. 16 Blue DPSS Laser-Civea473S H. 17 808 nm IR Laser ModuleOptics & Crystals Other Equipment H. 18 1064 nm IR Laser Module H. 19 Helium-Neon Laser Heads - 632.nm H. 23 Self-Contained Helium-Neon Laser Systems H. 25 Ultra Compact Fiber Laser Marker H. 26 CO2 Laser Marker H. 27 Scanning Head H. 28 IR Sensing CardG. 01 Production Line G - Lasers

GC. A B C D E F G H I Optical Tables H. 29 Laser Goggle Optical Tables H. 31 Laser Eyewear StagesGreen Laser Modules Laser Eyewear Education Systems Motion Systems Components Optical Mounts P LarersCO2 Laser Marker Helium-Neon Other Equipment Optics & Crystals Laser Heads - 632.nm Optics & Crystals Production Line G - Lasers G. 02

P Green Laser ModulesOptical Tables Diameter 8*30.5mm series — APC CW Mode Model GM-C803-001 GM-C803-005 Output Power Wavelength <1mW <5mW DimensionStages Beam Mode 532nm Operation Mode Beam Diameter Ħ8X30.5+/-0.5mm(without circuit) Beam Divergence Warm Up Time TEM00 Optimum Operating CW TemperatureOptical Mounts Operating Current <2mm at aperture Input Voltage Housing <1.2mrad < 3 sec. 20~30ɗComponents Motion Systems Education Systems <300mA 3V Brass ġ Diameter 8*30.5mm series — APC Pulse Mode Model GM-C802-001 GM-C802-005 Output Power Wavelength Peak <1mW Peak <5mW Dimension Beam Mode 532nm Operation Mode Beam Diameter Ħ8X30.5+/-0.5mm(without circuit) Beam Divergence Warm Up Time TEM00 Optimum OperatingLasers Temperature Pulse Operating Current Input Voltage <2mm at aperture Housing <1.2mrad < 3 sec.Optics & Crystals Other Equipment 20~30ɗ <300mA 3V BrassG. 03 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

QMT P TEL 886-3-4397556 FAX 886-3-4398379 http://www.opmount.com.tw @ [email protected] Diameter 8*33mm series with line beam — APC CW Mode Optical Tables Model GM-C803-01L GM-C803-05L Output Power Wavelength <1mW <5mW Dimension Beam Mode 532nm Stages Operation Mode Fan Angle Ħ8X33+/-1mm(without circuit) Line Width Warm Up Time TEM00 Optimum Operating CW Temperature Operating Current 90-120 degree Education Systems Motion Systems Components Optical Mounts Input Voltage Housing <5mm@5meter < 3 sec. 20~30ɗ <300mA 3V Brass Diameter 8*33mm series with line beam — APC Pulse Mode Model GM-C802-01L GM-C802-05L Output Power Wavelength Peak<1mW Peak<5mW Dimension Beam Mode 532nm Operation Mode Fan Angle Ħ8X33+/-1mm(without circuit) Line Width Warm Up Time TEM00 Lasers Optimum Operating Pulse Temperature Operating Current 90-120 degree Input Voltage Housing <5mm@5meter < 3 sec. 20~30ɗ Other Equipment Optics & Crystals <300mA 3V Brass www.opmount.com.tw bOP G. 04

P Green Laser ModulesOptical Tables Diameter 12*31.3mm series — APC CW Mode Model GM-CW02-001 GM-CW02-005 Output Power Model <1mW <5mW Output PowerStages Wavelength GM-CW02-010 GM-CW02-020 Dimension Beam Mode <10mW <20mW Operation Mode Beam Diameter 532nm Beam Divergence Warm Up Time Ħ12X31.3+/-0.5mm(without circuit) Optimum OperatingOptical Mounts Temperature TEM00 Operating Current Input Voltage CW Housing <1.5mm at aperture <1.2mrad < 3 sec.Components Motion Systems Education Systems 20~30ɗ <300mA 3V Brass Diameter 12*31.3mm series — APC Pulse Mode Model GM-PS02-001 GM-PS02-005 Output Power Model Peak<1mW Peak<5mW Output Power Wavelength GM-PS02-010 GM-PS02-020 Dimension Beam Mode Peak<10mW Peak<20mW Operation Mode Beam Diameter 532nm Beam DivergenceLasers Warm Up Time Ħ12X31.3+/-0.5mm(without circuit) Optimum Operating Temperature TEM00 Operating Current Input Voltage Pulse Housing <1.5mm at apertureOptics & Crystals Other Equipment <1.2mrad < 3 sec. 20~30ɗ <300mA 3V BrassG. 05 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

QMT P TEL 886-3-4397556 FAX 886-3-4398379 http://www.opmount.com.tw @ [email protected] Diameter 12*31.3mm series with line beam — APC CW Mode Optical Tables Model GM-CW02-01L GM-CW02-05L Output Power Model <1mW <5mW Output Power Wavelength GM-CW02-10L GM-CW02-20L Stages Dimension Beam Mode <10mW <20mW Operation Mode Fan Angle 532nm Line Width Warm Up Time Ħ12X31.3+/-1mm(without circuit) Optimum Operating Temperature TEM00 Education Systems Motion Systems Components Optical Mounts Operating Current CW Input Voltage Housing 90-120 degree <5mm@5meter < 3 sec. 20~30ɗ <300mA 3V Brass Diameter 12*31.3 mm series with line beam — APC Pulse Model GM-PS02-01L GM-PS02-05L Output Power Model Peak<1mW Peak<5mW Output Power Wavelength GM-PS02-10L GM-PS02-20L Dimension Beam Mode Peak<10mW Peak<20mW Operation Mode Fan Angle 532nm Line Width Warm Up Time Ħ12X31.3+/-1mm(without circuit) Lasers Optimum Operating Temperature TEM00 Operating Current Pulse Input Voltage Housing 90-120 degree <5mm@5meter Other Equipment Optics & Crystals < 3 sec. 20~30ɗ <300mA 3V Brass www.opmount.com.tw bOP G. 06

P Green Laser ModulesOptical Tables Diameter 12*33mm series — High Power ACC Version Model GM-XP01-030 GM-XP01-050 Output Power Model >30mW >50mW Output PowerStages Wavelength GM-XP01-060 GM-XP01-100 Dimension >60mW >100mW Beam Mode 532nm Operation Mode Beam Diameter Ħ12X31.3+/-0.5mm(30~50mW) Beam DivergenceOptical Mounts Optimum Operating Ħ12X33+/-0.5mm(50~100mW) Temperature TEM00 Operating Current CW Input Voltage <1.5mm at aperture Housing <1.5mradComponents Motion Systems Education Systems 20~30ɗ <400mA(30~50mW) <650mA(50~100mW) 3V Brass Diameter 12*33mm series with Line Beam — High Power ACC Version Model GM-XP01-30L GM-XP01-50L Output Power Model >30mW >50mW Output Power Wavelength GM-XP01-60L GM-XP01-100L Dimension >60mW >100mW Beam Mode 532nm Operation ModeLasers Fan Angle Ħ12X31.3+/-1mm(30~50mW) Optimum Operating Temperature Ħ12X33+/-1mm(50~100mW) Operating Current TEM00 Input Voltage CW HousingOptics & Crystals Other Equipment 90-120 degree 20~30ɗ <400mA(30~50mW) <650mA(50~100mW) 3V BrassG. 07 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

P TEL 886-3-4397556 FAX 886-3-4398379 http://www.opmount.com.tw @ [email protected] 12*36.5 mm seriers with focus adjustable beam — APC CW Mode Optical Tables Model GM-CF02-001 GM-CF02-005 Output Power Model <1mW <5mW Output Power Wavelength GM-CF02-010 GM-CF02-020 Stages Dimension Beam Mode <10mW <20mW Operation Mode Beam Diameter 532nm Warm Up TimeThis front cap can be adjusted to change the Optimum Operating Ħ12X36+/-0.5mm(without circuit)beam size(focus adjustable) Temperature Operating Current TEM00 Education Systems Motion Systems Components Optical Mounts Input Voltage CW Housing Adjustable < 3 sec. 20~30ɗ <300mA 3V BrassDiameter 12*36.5 mm seriers with focus adjustable beam — APC Pulse Mode Model GM-CFP2-001 GM-CFP2-005 Output Power Model Peak<1mW Peak<5mW Output Power Wavelength GM-CFP2-010 GM-CFP2-020 Dimension Beam Mode Peak<10mW Peak<20mW Operation Mode Beam Diameter 532nm Warm Up TimeThis front cap can be adjusted to change the Optimum Operating Ħ12X36+/-0.5mm(without circuit) Lasersbeam size(focus adjustable) Temperature Operating Current TEM00 Input Voltage Pulse Housing Adjustable < 3 sec. Other Equipment Optics & Crystals 20~30ɗ <300mA 3V Brasswww.opmount.com.tw bOP G. 08

P Green Laser ModulesOptical Tables Diameter 12*38 mm seriers with focus adjustable beam — High Power Version Model GM-CF02-030 GM-CF02-050 Output Power Model >30mW >50mW Output PowerStages Wavelength GM-CF02-060 GM-CF02-100 Dimension >60mW >100mW This front cap can be adjusted to change the Beam Mode 532nm beam size(focus adjustable) Operation Mode Beam Diameter Ħ12X36+/-0.5mm(30~50mW) Optimum OperatingOptical Mounts Temperature Ħ12X38+/-0.5mm(50~100mW) Operating Current TEM00 CW Input Voltage Housing AdjustableComponents Motion Systems Education Systems 20~30ɗ <400mA(30~50mW) <650mA(50~100mW) 3V Brass Diameter 20*58.5mm series — APC CW Mode Model GM-CW09-001 GM-CW09-005 Output Power Model <1mW <5mW Output Power Wavelength GM-CW09-010 GM-CW09-020 Dimension Beam Mode <10mW <20mW Operation Mode Beam Diameter 532nm Beam DivergenceLasers Warm Up Time Ħ20X58.5+/-0.5mm Optimum Operating Temperature TEM00 Operating Current CW Input Voltage Housing <1.5mm at apertureOptics & Crystals Other Equipment <1.2mrad < 3 sec. 20~30ɗ <300mA 3V BrassG. 09 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

QMT P TEL 886-3-4397556 FAX 886-3-4398379 http://www.opmount.com.tw @ [email protected] Diameter 20*58.5mm series with line beam — APC CW Mode Optical Tables Model GM-CW09-01L GM-CW09-05L Output Power Model <1mW <5mW Output Power Wavelength GM-CW09-10L GM-CW09-20L Stages Dimension Beam Mode <10mW <20mW Operation Mode Fan Angle 532nm Line Width Warm Up Time Ħ20X58.5+/-0.5mm Optimum Operating Temperature TEM00 Education Systems Motion Systems Components Optical Mounts Operating Current CW Input Voltage Housing 90-120 degree <5mm@5meter < 3 sec. 20~30ɗ <300mA 3V Brass Diameter 20*57.5mm series focus adjustable beam — APC CW Mode Model GM-CF09-001 GM-CF09-005 Output Power Model <1mW <5mW Output Power Wavelength GM-CF09-010 GM-CF09-020 Dimension Beam Mode <10mW <20mW Operation Mode Beam Diameter 532nm Warm Up Time Optimum Operating Ħ20X70.5+/-0.5mm Lasers Temperature Operating Current TEM00 Input Voltage Housing CW Adjustable < 3 sec. Other Equipment Optics & Crystals 20~30ɗ <300mA 3V Brass www.opmount.com.tw bOP G. 10

P Green Laser ModulesOptical Tables Diameter 50*50*34mm seriers—APC Version Model GM-CW04-001 GM-CW04-005 Output Power Model <1mW <5mW Output Power Model GM-CW04-010 GM-CW04-020 Output PowerStages Model <10mW <20mW Output Power Wavelength GM-CW04-030 GM-CW04-050 Dimension Beam Mode >30mW >50mW Operation Mode Beam Diameter GM-CW04-100 Beam DivergenceOptical Mounts Optimum Operating >100mW Temperature 532nm Operating Current Ħ50x50*34mm(without driver) Input Voltage TEM00 CW <1.5mm at apertureComponents Motion Systems Education Systems <1.5mrad 20~30ɗ <300mA(1-20mW) <400mA(30~50mW) <650mA(50~100mW) APC 9V with complete driver Diameter 50*50*34mm seriers with line beam—APC Version Model GM-CW04-01L GM-CW04-05L Output Power Model <1mW <5mW Output Power Model GM-CW04-10L GM-CW04-20L Output Power Model <10mW <20mW Output Power Wavelength GM-CW04-30L GM-CW04-50L Dimension Beam Mode >30mW >50mW Operation Mode Fan Angle GM-CW04-100L Optimum OperatingLasers Temperature >100mW Operating Current 532nm Input Voltage Ħ50x50*34mm(without driver)Optics & Crystals Other Equipment TEM00 CW 90-120 degree 20~30ɗ <300mA(1-20mW) <400mA(30~50mW) <650mA(50~100mW) APC 9V with complete driverG. 11 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

P TEL 886-3-4397556 FAX 886-3-4398379 http://www.opmount.com.tw @ [email protected] Power seriers with complete driver and power supply Optical Tables Stagesġ Education Systems Motion Systems Components Optical MountsġġġWavelength 532nm LasersModel GM-XP02-XXX(XXX means power)Output Power 100mW, 200mW, 300mW, 500mW Other Equipment Optics & CrystalsOutput Mode CW or Modulation (5V TTL Signal)Modulation Frequency 10KHz 50x50x110mmor 60x60x123mm (driver spec. excluded)Dimensionġ TEM00Beam Modġe <2.0mm <2.0mradBeam Diameter <10min. 15~35ɗBeam Diveġrgence AC 85-265VWarm Up Tġ ime CW or Modulation(5V TTL Signal)Optimum Operating TemperatureInput VoltageOutput Mode www.opmount.com.tw bOP G. 12

Optical Tables P Sigle Longitudinal Mode Green DPSS Laser Your Laser Solutions Single Frequency Laser TechnologyStagesOptical Mounts Key Features Applications Interference Photoluminescence Single-longitudinal Mode Raman Spectroscopy Micro-material Processing Low Noise <0.1% @ rms Biotechnology Bio-instrument Highest Reliability <1% Holography Precision Measurement Single-longitudinal Mode Confocal Microscope Chip Inspection Superior Performance DNA Sequencing Physics Experiments Flow Cytometry M <ഺ 1.05 Cell Sorting Long Lifetime 10000 hoursComponents Motion Systems Education Systems Specifications 523 mm Beam Divergence (full angle) < 1.0 mrad Wavelength CW Circularity of Beam > 95% Operating Mode 20,50 mW Output Power TEM സ സ Pointing Stability < 10 μrad Spatial Mode Single (rms,ovet 3 hours and 25±2C°) Longitudunal Mode < 1.05 Mode Quality M ഺ < 30 MHz Noise (0 Hz to 20 MHz) < 0.1% rms Spectral Linewidth > 100 m Coherent Length < 1.0 mm Power Stability (rms,ovet 24 hours) < ±1% Beam Diameter @1/e ഺ (Typical 0.8 mm ) Ploarization Ratio (Liner 45°) >100:1 Beam Height from the Base 20 mm Warm-up Time <10 minutes Expected Lifetime >10,000 Hours Ordering informationLasers Part NO. Output Power (mW) Laser Head End User Power Supply OEM Power Supply Action523Q-20 20 Action523Q-50Optics & Crystals Other Equipment Action523Q-100 50 100 Item NumberG. 13 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

PBlue DPSS Laser-Civea473L Fiber Illuminator Optical Tables Civea473L StagesKey Features Applications Scientific Experiments Education Systems Motion Systems Components Optical Mounts Optics Instrument Ultra Compact Collimation Biotechnology High Reliability Wafer Inspection Laser Display Superior Performance Micro-material Processing Laser Show Long Lifetime Metrology Printing Photoluminescence Medical Treatment Specifications 473 mm Beam Diameter @1/e ഺ 3.0mm±0.2mmWavelength CW Beam Divergence (full angle) < 2.0 mradOperating ModeOutput Power 800,1000 mW Beam Ellipticity > 10%Spatial ModeLongitudunal Mode Near TEM സ സ Pointing Stability < 0.05 mradMode Quality M ഺSpectral Linewidth Several Power Stabilitty (rms,over 4 hours) < ±10%TTL modulationAnalog modulation < 2.0 Polartization Ratio > 100:1 < 0.1mm Warm-up Time < 15 minutes Optional, 1-10kHz or higher (If erquest,higher rate up to 40kHz available) Optional, 1-10kHz or higher (0-max output when 0-5VDC signal input) 37 238 2521 54 Lasers 75 45 88 94 122 Front View 138 146 186.5 Side View 4-4* 10 35 Other Equipment Optics & Crystals 156 15825 78 Top View DPSSL DRI VER Power On Laser Alarm Off 12 Front View 12.5 160.5 Top View www.opmount.com.tw bOP G. 14

P Blue DPSS Laser-Civea473MOptical TablesStages Civea473MOptical Mounts Key Features Applications Scientific Experiments Optics Instrument Ultra Compact Collimation Biotechnology High Reliability Wafer Inspection Laser Display Superior Performance Micro-material Processing Laser Show Long Lifetime Metrology Printing Photoluminescence Medical TreatmentComponents Motion Systems Education Systems Specifications Wavelength 473 mm Beam Divergence (full angle) < 2.0 mrad Operating Mode Output Power CW Beam Ellipticity > 10% Spatial Mode Mode Quality M ഺ 150,200,300,500 mW Pointing Stability < 0.05 mrad Spectral Linewidth Beam Diameter @1/e ഺ Near TEM സ സ Power Stability (rams, over 4 hours) <±5%, <±10% TTL modulation < 2.0 Polarization Ratio >100:1 Analog modulation < 0.1 nm Warm-up Time <15 minutes 2.9 mm ± 0.2 mm Beam Height from the Base (mm) 29 mm Expected Lifetime >10,0000 Hours Optional,1-10 kHz or higher (If request,higher rate up to 40kHz avallable) Optional,1-10 kHz or higher (0~max output when 0~5VDC signal input) 21 238 20 55 46 60Lasers 130 78 29 122 Side View Front View 138 146Optics & Crystals Other Equipment 4-4* 10 35 15 6.5 158 67 Top View 94 DPSSL DRI VER 95 Power 130 On Laser Top View Alarm Off 12 Front ViewG. 15 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

PBlue DPSS Laser-Civea473SFiber Illuminator Optical Tables Civea473S StagesKey Features Applications Biomedicine Education Systems Motion Systems Components Optical Mounts Scientific Experiments Ultra Compact Fluorescence Sensors Optics Instrument High Reliability Raman Spectrum Laser Display Superior Performance Holography Laser Show Long Lifetime Submarine Communication Laser PrintingSpecificationsWavelength 473 mm Beam Divergence (full angle) < 1.5 mradOperating ModeOutput Power CW Beam Ellipticity > 10%Spatial Mode 10,20,30,50,80,100mWMode Quality M ഺ TEM സ സ Pointing Stability < 0.05 mradSpectral Linewidth < 1.2Beam Diameter @1/e ഺ < 0.1mm Power Stabilitty (rms,over 4 hours) < ±3% , ±5% 1.9mm±0.2mmTTL modulation Polartization Ratio > 100:1Analog modulation Warm-up Time < 15 minutes Beam Height from the Base (mm) 25mm Expected Lifetime >10,000 Hours Optional, 1-10kHz or higher (If erquest,higher rate up to 40kHz available) Optional, 1-10kHz or higher (0-max output when 0-5VDC signal input) Pow er Laser Alarm ON OFF 25 DPSSL DRI VER 49 45 61 95 130 Front View Back ViewFront View Side View 130 Lasers 50 75.6 135Back View 15 75 7 130 Other Equipment Optics & Crystals Top View 25 160 Top View 25 Side View 10.5 45 50 140 Front View 25.4 Top View Back View bOP G. 16 www.opmount.com.tw

P 808 nm IR Laser ModuleOptical TablesStagesOptical Mounts Available ModelComponents Motion Systems Education Systems Model LMIRL8-200 LMIRL8-500 Output Power Operating Current > 180mW > 450mW Laser Driver Dimension Laser Head Dimension < 400mA < 700mA 84 (L) x 54(W) x 43(H) mm^3 80 (L) x 55(W) x 34(H) mm^3 General SpecificationLasers Wavelength 808 nm Operating Voltage 9 V DCOptics & Crystals Other Equipment Output Mode CW Beam Size at Output ~1 mm @ X Axis ~ 3 mm @Y Axis Beam Divergence < 10 mrad @ X axis Operating Temperature < 1 mrad @ Y axis Power Stability Cooling 20~30ɗ Warm Up Time < 10%@ 25 ɗ Power Supply Air Cooling, with or without fan < 5 minutes AC 110/220V; 9V DC * Specific wavelength and better power stability are available upon request.G. 17 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

P1064 nm IR Laser Module Optical Tables Stages Available Model LMIRL1-200 LMIRL1-300 Education Systems Motion Systems Components Optical Mounts Model >200mW >300mWOutput PowerOperating Current <1200mA <1200mALaser Head Dimension 80 (L) x 55(W) x 34(H) mm^3 General Specification 1064 nm LasersWavelength 9VDCInput Voltage CW Other Equipment Optics & CrystalsOutput ModeBeam Divergence <1.4mradOperating Temperature 20~30 ɗPower Stability <10%@25 ɗCooling Air cooling with fanTTL ControlWarm Up Time <1KHzPower Supply <5mins AC110/220V; 9V DC* Better Power Stability at <3% or <5 % is also available upon request. bOP G. 18 www.opmount.com.tw

P Helium-Neon Laser Heads - 632.nmOptical Tables COMMERCIAL LASERSStages +HOLXP1HRQ /DVHU +HDGV 1100 6HULHVOptical Mounts Key Features ‡ /RQJ RSHUDWLQJ OLIH ‡ /RZ QRLVH ‡ ([FHSWLRQDO EHDPSRLQWLQJ VWDELOLW\ ‡ /RQJWHUP DPSOLWXGH VWDELOLW\Components Motion Systems Education Systems Applications Compliance ‡ )ORZ F\WRPHWU\ ‡ &( ‡ 0HWURORJ\ ‡ 789 ‡ 6HPLFRQGXFWRU LQVSHFWLRQ ‡ 8/ ‡ $OLJQPHQW ‡ &'5+UHJLVWHUHG ‡ /DVHULQGXFHG IOXRUHVFHQFH ‡ +HPDWRORJ\ ‡ +LJKVSHHG SULQWLQJLasers 7KH -'68  6HULHV UHG KHOLXPQHRQ ODVHU SURGXFWV RIIHU ORZ QRLVHKLJK SRZHU VWDELOLW\DQG ORQJ OLIH IRU WKH PRVW GHPDQGLQJ DSSOLFDWLRQV:LWK PRUH WKDQ  PLOOLRQ XQLWVOptics & Crystals Other Equipment VROG-'68 ODVHUV DUH WKH LQGXVWU\ VWDQGDUG IRU PDQ\ DGYDQFHG V\VWHP GHVLJQV -'68 PDQXIDFWXUHV KHOLXPQHRQ ODVHUV LQ WKH UHGJUHHQ\HOORZDQG RUDQJH ZDYHOHQJWKV$OO IHDWXUHV RXU SDWHQWHG FORVHFDWKRGH GHVLJQ WKDW UDSLGO\ DQGXQLIRUPO\ GLVWULEXWHV GLVFKDUJH KHDW WKURXJKRXW WKH ODVHUUHVXOWLQJ LQ H[FHOOHQW WKHUPDOEHDPSRLQWLQJDQG SRZHU VWDELOLW\2XU SDWHQWHG ILHOG FRQFHQWUDWRU GHVLJQ LJQLWHV WKH GLVFKDUJH ZLWKLQ PLOOLVHFRQGV RI DSSO\LQJ WKH VWDUW YROWDJH+DUGVHDOHG LQWHUQDO PLUURUVVPDOO SK\VLFDO VL]HDQG ORZ QRLVH UHVXOW LQ JUHDWHU UHOLDELOLW\ORQJHU OLIHDQG HQKDQFHG SHUIRUPDQFH $OO -'68 KHOLXPQHRQ ODVHUV DUH PDQXIDFWXUHG LQ D GHGLFDWHG IDFLOLW\ XVLQJ VWDWHRIWKHDUW SURFHVV FRQWURO WHFKQRORJ\7KLV HQDEOHV XV WR DFKLHYH KLJKHU SURFHVV \LHOGVDQG UHVXOWV LQ GHSHQGDEOH OHDG WLPHV DQG H[FHOOHQW RQWLPH GHOLYHU\ SHUIRUPDQFHG. 19 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

P TEL 886-3-4397556 FAX 886-3-4398379 http://www.opmount.com.tw @ [email protected] +(/,801(21 /$6(5 +($'6 Optical Tables2 (Specifications in inches unless otherwise noted.) Stages1100 Series Laser Heads / PD[ +LJK 9ROWDJH &DEOH  OHQJWK Education Systems Motion Systems Components Optical Mounts 2* 2*%HDP 2XWSXW $ ' GLD %  6LGH $FFHVVRU\ +RXVLQJ +ROHV 0 RQ   PP EROW FLUFOH  GLDPHWHU KHDG RQO\ )URQW Lasers3ODQH RI 3RODUL]DWLRQ ( 9HFWRU 1+ 8PELOLFDO &DEOH DQG +HDWHU /HDGV Other Equipment Optics & Crystals %DFN www.opmount.com.tw bOP G. 20

P Helium-Neon Laser Heads - 632.nmOptical Tables COMMERCIAL LASERSStages 3 Specifications Parameter 1101/P 1103/P/H 1107/P 1108/P 1122/P 1125/P 1135/P 1137/P 1144/P 1145/P UnitOptical Mounts Optical Min. output power (TEM00) 1.5 2.0 0.8 0.5 2.0 5.0 10.0 7.0 15.0 22.5/21.0 mW Wavelength 632.8 632.8 632.8 632.8 632.8 632.8 632.8 632.8 632.8 632.8 nm Mode purity (TEM00) >95 >95 >95 >95 >95 >95 >95 >95 >95 >95 % Beam diameter 0.63 0.63 0.48 0.48 0.48 0.81 0.68 0.81 0.70 0.70 mm (1/e² points, ±3%,TEM00) Beam divergence (TEM00, 1.3 1.3 1.7 1.8 1.3 1.0 1.2 1.0 1.15 1.15 mrad ±3%, mrad- full angle) Polarization ratio N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A -Components Motion Systems Education Systems (minimum, P versions) / 500:1 / 500:1 / 500:1 / 500:1 / 500:1 / 500:1 / 500:1 / 500:1 / 500:1 / 500:1 Longitudinal mod 730 730 1090 1090 730 435 320 435 257 257 MHz spacing (nominal) Maximum noise 0.1 0.1 0.1 0.1 0.1 0.2 1.0 0.2 0.5 0.5 % (rms, 30 Hz to 10 MHz) Max. drift (mean power ±2.5 ±2.5 ±2.5 ±2.5 ±2.5 ±2.5 ±3.0 ±2.5 ±2.0 ±2.0 % measured over 8 hours) Max. mode 33 10 20 3 2 2 2 1 1 % sweeping contribution Max. warm-up time 10 10 10 10 10 10 15 10 20 20 min. (minutes to 95% power) Beam pointing stability N / A N / A N / A N / A <0.10 <0.10 <0.10 <0.10 <0.20 <0.20 mrad (from cold start, 25 °C) Beam pointing stability N / A N / A N / A N / A <0.02 <0.02 <0.02 <0.02 <0.03 <0.03 mrad (after 15 minutes warm-up) Operating voltage 1700 1700 1250 1250 1800 2300 3100 2300 3800 3800 VDC (V DC ±100) Operating current 4.9 4.9 4.0 4.0 6.5 6.0 6.0 6.0 6.5 6.5 mA (±0.1 mA) Dimensions L-overall length 9.50 9.50 7.00 7.00 10.71 15.79 19.13 15.79 25.00 25.00 inches D-mounting diameter 1.245 1.245 1.245 1.245 1.740 1.740 1.740 1.740 1.740 1.740 inches (±0.005 inches) B-distance: cable end 1.00 1.00 0.75 0.75 1.50 3.00 4.00 3.00 5.00 5.00 inches to mounting surface A-distance: output end 0.75 0.75 0.50 0.50 1.50 3.00 4.00 3.00 5.00 5.00 inchesLasers to mounting surface CDRH/IEC60825-1 class IIIa / 3R IIIa / 3R IIIa / 3R II / 2M IIIa / 3R IIIa / 3B IIIa / 3B IIIa / 3B IIIa / 3B IIIa / 3B - (head &1200 Series power supply) General Maximum starting voltage 10 kV DC Mode purity >95%Optics & Crystals Other Equipment Storage lifetime Indefinite (hard-sealed) Static alignment Center to outer cylinder within ±0.01 inch. Parallel to outer cylinder within ±1 mR. Environmental Temperature -40 to 70 °C (operating), -40 to 150 °C (non-operating) Atitude 0 to 10,00 feet (operationg), 0 to 70,000 feet (non-operating) Relative humidity (no condensation) 0 to 100% Shock 25 g for 11 ms, 100 g for 1 ms Physical Laser Head weight 0.54 0.54 0.46 0.46 0.92 1.3 1.5 1.3 2.6 2.6 Ibs. Shipping weight 5 lb. (1100 Series heads); 10 lb. (1100 Series head and 1200 Series power supply)G. 21 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

P TEL 886-3-4397556 FAX 886-3-4398379 http://www.opmount.com.tw @ [email protected] HELIUM-NEON LASER HEADS Optical Tables4 Stages1103H Heating Element InputParameter Standard Maximum Education Systems Motion Systems Components Optical MountsVoltage 15.0 VDC 47.0 VDCCurrent 3.5 A 7.5 AHeater lead length >5 inches -Note: JDSU model 1103H laser heads are recommended for applications that require a frequency-stabilized HeNelaser source. The 1103H is filled with single-isotope Neon and equipped with a heating element which allows theuser to control the length of the laser cavity.Ordering InformationFor more information on this or other products and their availability,please contact your local JDSU account manageror JDSU directly at 1-800-498-JDSU (5378) in North America and +800-5378-JDSU worldwide or via e-mail [email protected]:1122PHelium-Neon laser heads require a matched power supply for normalFor additional HeNe power supply information,please refer to the HeNe power supply data sheet. Lasers Other Equipment Optics & Crystals www.opmount.com.tw bOP G. 22

Optical Tables PStages Self-Contained Helium-Neon Laser SystemsOptical Mounts COMMERCIAL LASERSComponents Motion Systems Education Systems SHOI&RQWDLQHG +HOLXmNHRQ LDVHU S\VWHmV 1500 6HULHV Key Features ‡ +DUGVHDOHG LQWHUQDO PLUURU SODVPD WXEH ‡ &RQYHQLHQWFRPSDFWVHOIFRQWDLQHG SDFNDJHV ‡ ([FHOOHQW SRZHU VWDELOLW\ ‡ &'5+ FRPSOLDQW ‡ /RQJ RSHUDWLQJ OLIH Applications 7KH 0RGHO  DQG  1RYHWWHŒ KHOLXPQHRQ ODVHU ‡ $OLJQPHQW V\VWHPV LQFRUSRUDWH KDUGVHDOHG LQWHUQDOPLUURU  ‡ 0HWURORJ\ DQG  SODVPD WXEHV DQG SRZHU PRGXOHV LQWR ‡ ,QVSHFWLRQ FRQYHQLHQW FRPSDFW VHOIFRQWDLQHG SDFNDJHV 7KHVH ORZFRVW XQLWV GHPRQVWUDWH VXSHULRU SRZHU VWDELOLW\ DQG Compliance PHHW &'5+ UHTXLUHPHQWV ‡ &'5+ ‡ &( 7KH EDVH RI WKH 1RYHWWH LV VORWWHG IRU HDV\ PRXQWLQJ $ WKUHDGHG ´  EH]HO DW WKH EHDP DSHUWXUH LQWHUIDFHVLasers ZLWK RSWLFDO DFFHVVRULHV $Q RSWLRQDO DGDSWHU SURYLGHV D ´ WKUHDGHG EH]HO SDUW QXPEHU Optics & Crystals Other EquipmentG. 23 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

P TEL 886-3-4397556 FAX 886-3-4398379 http://www.opmount.com.tw @ [email protected] 6(/)&217$,1(' +(/,801(21 /$6(5 6<67(06 Optical Tables1500 Series Novette™ Laser Systems (Specifications in inches unless otherwise noted.) Stages Broadband IPL Combinations 2.50 Education Systems Motion Systems Components Optical Mounts  2.00  $& DGDSWRU 2.2   '& SOXJ ZLWK  IRRW FDEOH2SpecificationsPDU DmHW HU 150 150P 150 150P UQLW2SWLFDO     mW Lasers0LQLPXP RXWSXW SRZHU 7(000     QP: DYHOHQJWK     mm Other Equipment Optics & Crystals%HDP GLDPHWHU 2HSRLQWV“ 7(000     PUDG%HDP GLYHUJHQFH “ 7(000 1$ 500:1 1$ 1$ %HDP GLYHUJHQFH PLQLPXP     0+]/RQJLWXGLQDO PRGH VSDFLQJ QRPLQDO 1.0 1.0 1.0 1.00D[LPXP QRLVH UPV 30 +] WR 10 0+] “ “ “ “ PLQ0D[LPXP GULIW PHDQ SRZHU PHDVXUHG RYHU  KRXUV 10 10 10 10 0D[LPXP PRGH VZHHS FRQWULEXWLRQ 10 10 10 100D[LPXP ZDUPXS WLPH PLQXWHV WR  SRZHU ,,,D ,,,D II II mA&'5+ FODVV mA(OHFWULFDO 150 150 150 150 mA 150 150 150 150$& DGDSWRU RSHUDWLQJ FXUUHQW     DW 9 $& DW 9 $& ! DW 9 $&  OEV*HQHUDO0RGH SXULW\+HDG ZHLJKW www.opmount.com.tw bOP G. 24

P Ultra Compact Fiber Laser MarkerOptical Tables application materialStages Metal and nonmetallic materials are all applicable.Optical Mounts Suitable for the various types of hands tool, motorcycle, car, bicycle part, bit,bearing, sanitary equipment, mechanical parts, medical apparatus, musical instrument, watch, electronic part,IC,PCB board, button, panel,connector...etc.Components Motion Systems Education Systems Overview Energy-conservation saves the electricity and saves the space, plug and play 1~500KHz repetition rate,versatile and helpful Unique waveform design, each frequency provide highest energy Offer the CW mode, in extensive application range High speed, ultra compact with high precision performance scanning head, suitable for all for variable application Specification Wavelength(nm) 1065 ± 5 Laser Type Pulsed Fiber Laser M2 <2 Output Power(max.) 20Watts Pulsed Repetition Range CW and 1~500KHz F-Theta Lens SLF163 SLF254 Working Distance(mm) 201 325Lasers Field Size(mm) 90x90 150x150 Spot Size@TEM00(um) 40.5 51.6 Marking Speed(mm) >5000Optics & Crystals Other Equipment Dimensions of Control Cabinet (mm) 215(W)x275H)x480(D) Dimensions of Laser Head (mm) 470(L)x92(W)x130(H) Weight of Control Cabinet (Kg) 18 Weight of Laser Head (Kg) 5 Electrical Power 1 ĭ100~240 VAC, 50/60 Hz , 3.0 AMP Control Interface USB Mode PC Requirement Windows XP/ Vista / Windows 7 Based, USB Port ɈSPECIFICATIONS SUBJECT TO CHANGE WITHOUT NOTICEɈG. 25 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

PCO2 Laser Marker application material Optical Tables Any non-metal material such as glass, plastic, Stages acrylic, wood, coating, spray paint, anodize, oxidate, stick...etc. Material: Electronic units, IC, PCB, button, CD disc, coneector, packing material, photo frame, cotton material... etc.Overview Education Systems Motion Systems Components Optical MountsNon-contact manufacture, without any changing cutter and breaking problemWith permanent mark and exquisite qualityComputer drafting can save the molding inconvenienceThis machine applies to various materials and there is no limitation in the hardness.It can mark on the object directly without cleaning the surface and also simplifyproductive proceduresCan be used on surface processingAutomated design is applicative from small to large number productionsWavelength 10.6umLaser Type Sealed, RF Excited CO2 LaseBeam Mode TEM00, 95% Purity, M2<1.2Output Power (max.)Pulse Width Modulation 10WattsScan Lens ~20KHzWorkin Distance mmField Size (mm) F70 F110Spot Size (um)Marking Speed (mm) 102.5 147.1Dimensions of Laser Head (mm)Weight of Laser Head (Kg) 70 × 70 110 × 110 LasersCooling Requirement 130 210Electrical PowerControl Interface 5000PC Requirement 758(L)× 173(W)× 236(H) Other Equipment Optics & CrystalsɈSPECIFICATIONS SUBJECT TO CHANGE WITHOUT NOTICEɈ 15 Fans 1ࢥ 100~240 VAC, 50/60 Hz , 2.5 AMP 16Bit Digital USB Mode Windows XP / Vista Based , USB Port www.opmount.com.tw bOP G. 26

Optical Tables PStages Scanning Head THE BEST SOLUTION FOR Laser Marking ApplicationOptical MountsComponents Motion Systems Education Systems Specification 355nm, 532nm, 1064nm, 10.6umLasers Wavelength 10mm 14mm Input Aperture Small Angel Response 0.25ms 0.4ms Input Signal Status Output 16Bit Analog or 16Bit Digital Electrical PowerOptics & Crystals Other Equipment Outline Dimension Power / Temperature Weight(Exclude F-theta lens) Ʋ15VDC炻5A 188Lx120Wx147H(mm) 3.3KgG. 27 bOP OP Mount Instrument Inc. w w w . o p m o u n t . c o m . t w

PIR Sensing Card Optical Tables Functions Stages 42mm Education Systems Motion Systems Components Optical Mounts 54mmOP Mount's infrared sensor card has edge-to-edge large active area and produced inthe PVC ISO card standard format with reflective base.This edge-to-edge active areawill facilitate our card users with ease during the laser alignment and infrared detection.Besides that, its matt surface finishing will also reduce and minimize the glare of laserbeam reflecting back during the same alignment and infrared detection process. Part No. IR-card Lasers Green 545nm @950~980nm Peak Emission (color/nm) Red 670nm @1500~1600nm Other Equipment Optics & Crystals Red 650nm @other wavelenths Excitation Range (nm) 800~1600nm, especially at 950nm, 980nm, 1064nm, 1500nm Pumping Wavelength UV to Visible Base Material PVC ISO Approx Min IR intensityApprox Min IR intensity (In Dark Room) At least 3800uW/cm2 @1550nm At least 67uW/cm2 @1550nm Active Size (mm) 54x42mm Reflective or Transmissalbe Reflective www.opmount.com.tw bOP G. 28