mAC-C-400-24 mini Air Cooler Cabinet Cooler

Proof test: 100 kpsi. Bend insensitive, high index single mode specialty optical fibers. Key optical specifications Operating Wavelength (nm)  > 780 Cutoff Wavelength (nm)  720 ± 50 Maximum Attenuation (dB/km)  4.3 @ 780 nm    3.0 @ 850 nm  Mode-field Diameter (µm)  4.6 ± 0.5 @ 780 nm    5.0 ± 0.5 @ 850 nm             Key geometric, mechanical and environmental specifications Cladding Outside Diameter (µm)  125 ± 0.5 Coating Outside Diameter (µm)  245 ± 10 Core-to-Cladding Offset (µm)  ≤ 0.3 Standard Lengths  500 m, 1 km, 2 km, 5 km, 10 km Proof Test (kpsi)  100 Operating Temperature (°C)  -60 to 85           Performance characterizations* Nominal Delta (%)  0.45 Numerical Aperture  0.14 Refractive Index Value-Core  1.463 @ 651 nm Bendloss (20 mm O.D.; 850 nm) (dB/turn)  < 0.05  Dispersion (ps/nm/km)  -132 @ 780 nm    -99 @ 850 nm Core Diameter (µm)  4.0             * Values in this table are nominal or calculated values

Receptacle Style; 375 to 2000 nm; Wavelength Accuracy ±5 to ±30 nm; Coupling Efficiency 10% to 75%; Fiber Type SM, MM or PM OZ Optics’ HULD series of receptacle style laser diode to fiber couplers is offering optimum coupling in a small, rugged package. The couplers may be purchased prealigned, with the diode already in place, or as a kit that can be assembled by the customer using their own diode. The complete assembly procedure is quite straightforward. An assembly and operating instruction video on a USB drive, showing the alignment process, is available. In addition, a complete alignment kit is available, which includes the laser diode collimation wrench, multimode fiber assembly, centering lens, and video instructions. Diode source couplers are available for a variety of diode case sizes, and for diode wavelengths from 375 nm to greater than 2000 nm. These source couplers work with MM, SM and PM fiber. HULD connector receptacle style couplers have a female receptacle, such as NTT-FC, or AT&T-ST, etc. at the output end. This allows the user to connect any optical fiber with a matching male connector to the diode. HULD laser diode to fiber couplers are available in different diameters from 0.79 inch to 1.3 inch. These tilt adjustable source couplers can be used over a temperature range of -25 °C to +60 °C and have been vibration tested. Higher temperature versions are available on request OZ Optics also offers special, low cost, miniature receptacle style laser diode to fiber couplers for OEM applications. These packages use just a single lens to couple light from the laser diode into the fiber. They do not use OZ Optics tilt adjustment technique. This package features a compact, rugged housing, at a lower cost. A variety of options like a built-in isolator, a blocking screw to attenuate the output beam as well as polarizers or polarization rotators in the middle are also available. Key Features: 375nm to 2000nm Variety of Standard Packaging Options SM, MM or PM fiber Rugged Design Custom Design for Diodes High-power Version Applications: Fiber Optic Communications; Optical Alignment Systems; Process Control; Optical Sensors; Medical Apparatus; Imaging Systems ; Test and Measurement Systems

Focal Length 1.50-22.00 mm; Numerical Aperture 0.13-0.71; Design Wavelength 405-7800 nm; Outer Diameter 6.24-14.25 mm; Thread MT6, MT8, MT9, MT12, MT14 With 27 of GH Optics’ standard precision molded aspheric lenses mounted into five different stainless steel lens holders, this series of components allow for very easy assembly. Our mounted precision molded aspheric lenses feature MT6, MT8, MT9, MT12 or MT14 threads for screwing the components into your systems, but they can also be soldered or welded to suitable structures in the required position. GH Optics’ series of mounted precision molded glass aspheric lenses can be used for applications in the visible (VIS) and infrared (IR) wavebands, such as small beam collimation, focusing, and fiber coupling. In these applications, aspheric lenses avoid spherical aberrations known from spherical lenses and can therefore reduce the complexity of both the design process and the resulting optical system. While the cost and effort involved in the traditional production of aspheric lenses has often prevented the use of this type of lens in cost-sensitive applications, GH Optics manufactures affordable aspheric lenses with high, reproducible quality by molding glass preforms in molds of high precision. On request, most aspheric lenses in our portfolio can be mounted into a custom assembly specified by the customer. For large-volume applications we recommend to contact your regional AMS Technologies office, so that we can tailor a solution based on your technical needs. Three types of glass are available for our series of mounted precision molded aspheric lenses for visible and NIR wavelenghts, all RoHS compliant: Lens Series Glass Type Refractive Index Abbe Number CTE dn/dT RoHS Compliance MD D-ZK3 1.586 60.71 7.6×10-6/°C 3.2×10-6/°C yes ME D-ZLaF52La 1.806 40.79 6.9×10-6/°C 6.5×10-6/°C yes MG D-LaK6 1.690 52.65 6.9×10-6/°C 6.5×10-6/°C yes   For our mounted precision molded infrared aspheric lenses, two types of chalcogenide glass are available, comparable to infrared glass of other leading brands in the market and featuring high transmission as well as RoHS compliance:  Lens Series Glass Type Glass Material Refractive Index @10 µm Abbe Number @10 µm CTE dn/dT RoHS Compliance M2 GH2 Ge28Sb12Se60 2.6044 93.63 142×10-7/°C 70.4×10-6/°C yes M6 GH6 As40Se60 2.7775 137.71 209×10-7/°C 31.3×10-6/°C yes   Mounted precision molded aspheric lenses for visible and NIR wavelengths can be coated with a range of visible and NIR coatings, including four standard AR coatings (VA, VB, VC, VQ) featuring average reflectance values of ≤0.6%, ≤0.5%, or even ≤0.25%, for wavelength ranges of 380 nm to 700 nm, 600 nm to 1100 nm, 1050 nm to 1650 nm, or 1300 nm to 1700 nm respectively. Other customized coatings like HD (High Density) or SWB (Short Wave Blocking) are available on request. Lens Code Thread Outer Diameter (OD) Effective Focal Length (EFL) Lens Numerical Aperture (NA) Clear Aperture (CA) Design Wavelength (DW) MD1560 MT6 6.24 mm 1.50 mm 0.58 1.60 mm 780 nm MF2570 MT8 8.24 mm 2.50 mm 0.66 3.30 mm 405 nm ME2860 MT8 8.24 mm 2.80 mm 0.64 3.60 mm 830 nm MD3170 MT9 9.24 mm 3.10 mm 0.68 5.00 mm 830 nm MD4060 MT9 9.24 mm 4.00 mm 0.64 5.10 mm 685 nm MG4060 MT9 9.24 mm 4.00 mm 0.60 4.80 mm 408 nm MD4530 MT6 6.24 mm 4.50 mm 0.30 2.70 mm 635 nm MD4540 MT8 8.24 mm 4.50 mm 0.40 3.70 mm 980 nm ME4560 MT9 9.24 mm 4.50 mm 0.55 5.07 mm 780 nm MD4650 MT9 9.24 mm 4.60 mm 0.54 4.80 mm 655 nm MD5020 MT6 6.24 mm 5.00 mm 0.15 1.60 mm 1550 nm MD5560 MT9 9.24 mm 5.50 mm 0.58 6.00 mm 635 nm MD6020 MT8 8.24 mm 6.00 mm 0.21 2.50 mm 1550 nm MD6230 MT8 8.24 mm 6.20 mm 0.30 3.70 mm 635 nm ME6240 MT9 9.24 mm 6.20 mm 0.40 5.00 mm 780 nm ME7530 MT9 9.24 mm 7.50 mm 0.30 4.54 mm 780 nm MD8050 MT12 12.22 mm 8.00 mm 0.50 8.00 mm 780 nm MD9630 MT9 9.24 mm 9.60 mm 0.27 5.20 mm 635 nm MD9930 MT9 9.24 mm 9.90 mm 0.27 5.20 mm 650 nm MDA050 MT14 14.25 mm 10.00 mm 0.51 10.00 mm 635 nm MDA130 MT9 9.24 mm 11.00 mm 0.25 5.50 mm 635 nm MDA320 MT9 9.24 mm 13.00 mm 0.20 5.20 mm 633 nm MDA520 MT9 9.24 mm 15.30 mm 0.16 5.00 mm 785 nm MDA820 MT9 9.24 mm 18.40 mm 0.15 5.50 mm 785 nm MDB210 MT9 9.24 mm 22.00 mm 0.13 5.50 mm 670 nm M23070 MT9 9.24 mm 3.00 mm 0.71 5.00 mm 7.8 µm M24060 MT9 9.24 mm 4.00 mm 0.56 5.00 mm 4.0 µm    Key Features: Stainless Steel Holder Assembly With Glue Threaded Interface for Easy Assembly Rapid Prototype Focal Length: 1.50 mm to 22.00 mm Lens Numerical Aperture: 0.13 to 0.71 Design Wavelength: 405 nm to 7.8 µm Assembly Outer Diameter: 6.24 mm, 8.24 mm, 9.24 mm, 12.22 mm, 14.25 mm Thread: MT6, MT8, MT9, MT12, MT14 Applications: Laser; Telecom; Medical; Imaging; And Many More  

2-12 µm; Active Area 0.0025, 1 mm²; Responsivity ≥5.0x101-≥6.5x104 V/W; Detectivity ≥5.0×106-≥2.3×1010 cm·Hz1/2/W; Power Supply +5,+9 VDC Vigo System’s UM, LabM, UHSM and MicroM selected line series of infrared (IR) detection modules integrate the infrared photodetector with signal processing electronics, optics, heat dissipation systems and other components in a common package – resulting in very convenient and user‑friendly devices that can be easily used in a variety of MWIR/LWIR applications. This integration makes the detectors less vulnerable to over-bias, electrostatic discharge, electromagnetic interference (EMI) and other environmental exposures. Additional advantages of the integration are improved high-frequency (HF) performance, output signal standardization, miniaturization, and cost reduction. Vigo System’s selected product line guarantees a short order fulfillment date and an effective price. Vigo System offers detection modules with an infrared detector optimized for uncooled operation or for temperatures achievable with Peltier-coolers in the spectral range from 2 µm to 12 μm. IR radiation emitted by an object is concentrated on the active area of an IR detector, generating photoelectric signals which are sensed by the front-end electronics (FEE). The front-end electronics circuitry is typically used to: Provide optimum conditions for the operation of IR detectors (to achieve high sensitivity, fast response, and a wide dynamic range. This is typically achieved with optimized constant voltage bias and current mode of the photoelectric signal readout.) Protect detector elements against overbias Amplify the signal within the required frequency band. This could be done with a minimized contribution of the preamplifier noise to the resulting noise of the detection module. In addition to front-end electronics, detection modules may include additional electronic blocks for signal conditioning, such as gain blocks, filters, thermoelectric cooler controllers, analog-digital converters (ADC) and other components. Except for MicroM, these IR detection modules feature 3° wedged zinc selenide anti-reflection coated windows preventing unwanted interference effects. Vigo System’s UM series features universal „all-in-one” 3.0 µm to 6.7 μm and DC to 1 MHz (UM-I-6) as well as 2 µm to 12 μm and DC to 70(100) MHz (UM-(I-)10.6) HgCdTe IR detection modules. A thermoelectrically cooled (for some models optically immersed) photovoltaic detector, based on HgCdTe heterostructure, is integrated with a transimpedance, DC-coupled preamplifier, a fan and a thermoelectric cooler controller in a compact housing. Vigo System’s LabM series of programmable detection modules enable control of many parameters, such as bandwidth and gain, even during normal operation. This opens up completely new possibilities to designers of measuring systems. In a fully analogue input circuit, many switching elements are used, even with a variable, digitally-controlled capacitance to compensate the transimpedance input stage. Within the LabM series, 3.0 µm to 7.5 μm and over 200 MHz (LabM-I-6) and 2 µm to 12 μm and DC to 100 MHz (LabM-I-10.6 ) HgCdTe programmable, laboratory IR detection modules are available, with optically immersed photovoltaic detectors based on HgCdTe heterostructure, integrated with a transimpedance, programmable preamplifier. Vigo System’s UHSM series of convenient and user‑friendly ultra-high-speed detection modules aims at LWIR applications requiring high-time-resolution or high-frequency-bandwidth optical detection. Electronics and mechanics have been designed specifically to support the propagation of high-speed signals. Within the UHSM series, 3 µm to 12 µm and over 1 GHz (UHSM-10.6) or 700 MHz (UHSM-I-10.6) HgCdTe ultra high speed „all-in-one” IR detection modules are available. Thermoelectrically cooled, photovoltaic detectors (optically immersed for UHSM-I-10.6), based on HgCdTe heterostructure, are integrated with a transimpedance, AC coupled preamplifier, a fan and a thermoelectric cooler controller in a compact housing. Vigo System’s MicroM is a micro-size detection module with uncooled photovoltaic multiple junction detector. It is optimized for operation in the spectral range from 2 μm to 12 μm and frequency bandwidth from DC to 10 MHz. It is easy to assemble in space-limited measuring systems for long wavelength infrared (LWIR) applications. Key Features: Very High Performance and Reliability Integrated TEC Controller and Fan (UM, UHSM) Very Small Size (MicroM) Single Power Supply: +5 VDC, +9 VDC DC Monitor (UM, SHSM) DC Offset Compensation (LabM) Parameters Configurable by the User (LabM): Output Voltage Offset; Gain (in 40 dB Range); Bandwidth (1.5 MHz/15 MHz/200 MHz); Coupling AC/DC; Detector’s Parameters (Temperature, Reverse Bias etc.) Sensitive to IR Radiation Polarization (UM(-I)-10.6, ) LabM-I-10.6, MicroM) Optimized for Effective Heat Dissipation Wide Frequency Bandwidth Over 1 GHz (UHSM) Compatible With Optical Accessories Cost-effective OEM Version Available Universal, Versatile & Flexible, Convenient to Use Fast Delivery Active Element Material: Epitaxial HgCdTe Hetereostructure Active (Optical) Area: 1x1 mm², 0.05x0.05 mm² Cut-on Wavelength λcut-on (10%): ≤2.0 to 3.0 μm Peak Wavelength λpeak: 5.2 to 9.5 μm Optimum Wavelength λopt: 6.0 to 10.6 μm Cut-off Wavelength λcut-off (10%): 6.7 to 12.5 μm Detectivity D*: ≥1.50x107 to ≥2.3×1010 cm·Hz1/2/W (λpeak), ≥5.0×106 to ≥1.5×1010 cm·Hz1/2/W (λopt) Output Noise Density vn (100 kHz): ≤70 nV/Hz1/2 to ≤400 µV/Hz1/2 Voltage Responsivity Rv: ≥1.2x102 to ≥6.5x104 V/W (λpeak), ≥5.0x101 to ≥3.6x104 V/W (λopt) Low Cut-off Frequency flo: DC to 300 Hz High Cut-off Frequency fhi: ≥1 MHz to ≥1.0 GHz Infrared Windows: None, wZnSeAR Acceptance Angle Φ: ~36° to ~85° Applications: Leak Detection; Gas Detection, Monitoring and Analysis (CO, CO2, NH3, NOx); CO2 Laser Measurements; Laser Power Monitoring & Control; Laser Beam Profiling & Positioning; Laser Calibration; Characterization of Pulsed Laser Sources; Flue Gas Denitrification; Fuel Combustion Monitoring at Power Plants and Other Industrial Facilities; Breath Analysis; Explosion Prevention; Contactless Temperature Measurement & Control; Semiconductor Manufacturing; Glucose Monitoring; Dentistry; Dual-comp Spectroscopy; Heterodyne Detection; LIDAR; Object Scanners; Time-resolved Fluorescence Spectroscopy; Free-space Optical Communication