手持/便携拉曼光谱仪 532/785/1064 nm
高分辨率光纤光谱仪(200nm-1100nm)
背照式高灵敏紫外光谱仪(200nm-1100nm)
背照式制冷高灵敏光谱仪(200nm-1100nm)
大型数值孔径高灵敏度光谱仪(200-1450nm)
高通量近红外光谱仪(900-2500nm)
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SIMSCOP单点共聚焦显微镜
SIMSCOP线扫共聚焦显微镜
SIMSCOP转盘共聚焦显微镜
SIMSCOP结构光SIM显微镜
SIMSCOP宽场拉曼显微镜
多线连续单模激光器
用于SPAD(APD)测试的TCSPC系统
无掩膜紫外光刻机
多点激光多普勒测振仪 0.1Hz to 5Mhz
OCT成像系统
新品上线
X-ray/XRD 冷热台
光学冷热台
电探针温度台
可调电探针台
拉伸应变温度台
光纤光谱仪 (200nm to 5um)
手持/便携拉曼光谱仪 532/785/1064nm
X射线/极紫外光谱仪 (1-300nm)
高光谱相机 (220nm-4.2μm)
多光谱相机 (400-1000nm)
分光光度计(240-2150nm)
光电倍增管 (PMTs)
可见光单光子探测器(SPD)
红外单光子探测器(SPD)
光电二极管PD(200nm-12um)
热电红外探测器(2-12um)
光电探测器模块
红外光束分析仪(2-16um)
太赫兹光束分析仪(3-20 THz)
扫描狭缝光束轮廓仪(190-2500nm)
光功率计探测器 250-2500nm
功率计控制台
光功率计积分球
电力仪表适配器及附件
VUV/UV摄谱仪
1/8m 单色仪/光谱仪
1/2m &1/4m 单色仪/摄谱仪
单色仪配件
过滤器&滤光片轮
LIV测试系统(LD/LED)
激光多普勒测振仪 0.1Hz to 5Mhz
白光干涉仪
光学镀膜CRD反射计
光学测试测量系统
射频测试测量系统
连续尾纤激光二极管(400-1920nm)
连续激光二极管模块 (375-785nm)
连续多波长激光器
DPSS纳秒脉冲激光器
DFB/FP皮秒激光器(370-1550nm)
高功率飞秒固体激光器
纳秒脉冲光纤激光器(1064-2um)
皮秒脉冲光纤激光器 (515nm - 2um)
飞秒脉冲光纤激光器 780nm-2um
CW光纤激光系统(405nm-2um)
连续窄线宽激光器(1530nm-2um)
C波段可调谐激光器(1529 -1567nm)
L波段可调谐激光器(1554 -1607nm)
超级连续光谱光纤激光器(450-2300nm)
飞秒激光放大器 (650 - 2600nm)
短脉冲OPA(650-2600nm)
宽带飞秒激光器(950-1150nm)
掺铒光纤放大器
掺镱光纤放大器
掺铊光纤放大器
光纤拉曼放大器
半导体光放大器 (SOA)
真空紫外光源
紫外光源
显微镜光源(185-5500nm)
单波长LED光源(240-980nm)
中红外光源
多波长LED光源(240-980nm)
光场合成器
中空纤维压缩机
大功率空心光纤压缩机
超高对比度三阶自相关器
相干超宽带XUV光源
用于激光的增强型腔
太赫兹量子级联激光器(1-4.5Thz)
连续红外量子级联激光(3-12um)
连续长波红外量子级联激光(10-17um)
全自动荧光显微镜
SIMSCOP宽场共焦拉曼显微镜
SIMSCOP科研线扫共聚焦显微镜L系列
宽带手持式共聚拉曼皮肤分析仪
荧光正置/倒置显微镜
生物正/倒置显微镜
相差正置显微镜
暗视野正置显微镜
偏光正置显微镜
金相正置/倒置显微镜
智能三维体视显微镜
USB数字显微镜-带平台
内置数码显微镜
测量仪
金相显微镜
光学测量仪
平场复消色差物镜
工业计划物镜
生物计划物镜
显微镜CCD相机(VIS-NIR)
显微镜 CMOS 摄像头(紫外一近红外)
UV&NIR 增强型CMOS相机
用于显微镜的高光谱相机
用于显微镜的多光谱相机
显微镜光源
软X射线 BSI SCMOS摄像头(80-1000eV)
UV-NIR sCMOS 相机(200-1100nm)
增强型CMOS相机(200-1100nm)
激光增强管
全帧CCD相机(UV VUS NIR)
全帧CCD相机(VUV EUV X-ray)
全画幅真空CCD相机
大幅面真空CCD相机
显微镜CMOS摄像头(紫外一近红外)
UV&NIR增强型CMOS相机
高清晰度多媒体彩色CMOS摄像头(显示器)
高速线扫描摄像机
大幅面摄像机
高速大幅面摄像机
帧抓取器
热释电红外探测器(2-12um)
红外高温计(-40-3000C)
红外线阵列相机
红外线面振相机
黑体校准源 -15 to 1500°C
短波红外摄像机(SWIR)
中波红外摄像机(MWIR)
长波红外摄像机(LWIR)
自由空间声光调制器(AOM)
光纤耦合声光调制器
声光可调滤波器 (AOTF)
声光Q开关 (AOQ)
声光频移 (AOFS)
相位调制器
用于TCSPC的超快脉冲发生器
单光子时间计数器
ID1000定时控制器
电光强度调制器
电光相位调制器
通用脉冲发生器
中高压脉冲发生器
高速脉冲发生器
超高速脉冲发生器
函数发生器
脉冲放大器
脉冲电压
脉冲电流
相位型空间光调制器
振幅型空间光调制器
数字微镜空间光调制器
TPX/HDPE太赫兹平面凸透镜
离轴抛物面反射镜
太赫兹空心逆向反射器
太赫兹金属反射镜
ZnTe/GaSe太赫兹晶体
太赫兹扩束反射
波片
光隔离器
光学偏振片
光束挡板
分束器立方体
二向色分束器
超薄光束挡板
带通滤波器
拉曼光谱滤波器
激光窄滤波器
FISH过滤器
TIRF显微镜过滤器
FRET显微镜过滤器
激光晶体
非线性光学晶体
双折射晶体
光学晶体
电光晶体
微通道板(MCP)
微通道板组件(MCP)
光纤板(FOP)
微孔光学
X射线准直器
混合纤维组件
电动可调光纤延迟线
手动可调光纤延迟线
光学循环器
滤波器耦合器
FA透镜
变焦镜头
电控探针冷热台
外部调节探针冷热台
原位拉伸冷热台
XRD/SEM 原位冷热台
单轴电动压电载物台
XY电动压电载物台
多轴电动压电载物台
XY显微镜压电载物台
真空无磁压电动台
纳米电动执行器
透镜支架
镜架
过滤器支架
13mm 线性位移台
25mm 线性位移台
旋转和倾斜台
齿条和小齿轮级
垂直轴台
2轴台
固体隔振光学台
固体隔振台
气动光学台
带摆杆的气动光学台
蜂窝式光学电路板
The 980-1080nm Multi-mode Optical Circulator, designed for up to 20W applications, ensures low insertion loss and high return loss. It's recognized for its high isolation and stability, making it reliable for fiber lasers, testing instruments, and fiber instruments. This circulator is ideal for scenarios requiring robust performance in multimode optical contexts.
Features
Applications
Specifications
Parameters
Unit
Value
Center Wavelength
nm
1064, 1030, 980
Operating Wavelength Range
±5
Typ. Peak Isolation
dB
20
Min. Isolation at 23℃
18
Typ. Insertion Loss at 23℃
1.0
Max. Insertion Loss at 23℃
1.3
Max. Polarization Dependent Loss at 23℃
0.15
Min. Return Loss at 23℃ (Input/ Output)
30
Min. Cross Talk at 23℃
35
Max. Optical Power (CW, Including Port 1 & Port 2)
W
1, 2, 5, 10 or Specified
Max. Peak Power for ns Pulse
kW
10
Max. Tensile Load
N
5
Package Dimension
mm
70x28x26
Fiber Type
-
MM50/125 or MM62.5/125
Operating Temperature
℃
+10~+50
Storage Temperature
0~+60
*With connectors, the Max. handling power is 1W only, IL will be 0.3dB higher, RL will be 5dB lower.
Package Dimensions
Ordering Information
STMMCIR-①①①①-②-③③③-④⑤-⑥-⑦⑦⑦-⑧⑧⑨⑨
①①①①
- Center Wavelength:
1064=1064nm, 1030=1030nm, 980=980nm, SSSS=Specified
②
- Port Type:
3=3-port
③③③
- Fiber Type:
010=MM50/125, 093=MM-62.5/125
④
- Package Dimensions:
0=70x28x26mm, S=Specified
⑤
- Pigtail Type:
0=bare fiber, 1=900μm loose tube
⑥
- Fiber Length:
0.8=0.8m, 1.0=1m, S=Specified
⑦⑦⑦
- Connector Type:
0=FC/UPC, 1=FC/APC, 2=SC/UPC, 3=SC/APC, N=None, SS=Specified
⑧⑧
- Handling Power:
01=1W, 05=5W, 10=10W, SS=Specified
⑨⑨
- Peak Power:
00=Continuous Wave, 01=1kW, 02=2kW, 10=10kW, SS=Specified
Q:What is Optical Circulator?A:An Optical Circulator is a non-reciprocal three or more port device, allowing light to travel in only one direction from one port to the next. It's widely used in advanced fiber optic systems for directing light between components without back reflection issues, thus used in applications like fiber amplifiers, fiber sensors, and fiber lasers to enhance signal fidelity and system efficiency.
Q:What does Optical Circulator's Port Type mean?A:In an Optical Circulator, "Port Type"refers to the specific kind of connector used for attaching the circulator to optical fibers. It's crucial for ensuring compatibility and efficient light transmission between the circulator and the optical fiber system. Different port types (e.g., FC, SC, LC) offer varied physical and performance characteristics, affecting aspects like connection stability, insertion loss,and ease of use in fiber optic networks.
Q:What is Optical Fiber Circulator Applications ?
A:Optical Fiber Circulators have a wide range of applications across various fields, primarily due to their ability to direct light between different parts of a fiber optic system without back reflection. Some of the key applications include:
1. Fiber Optic Communications: Circulators are used to separate incoming and outgoing signals in fiber optic networks, enhancing the efficiency and capacity of the communication system.
2. Fiber Amplifiers (EDFA, Raman Amplifiers): Circulators are used to direct light through amplifier fibers, allowing for the amplification of weak signals in long-distance communication or high-power applications.
3. Fiber Sensors: In sensing applications, circulators are used to route signals to and from the sensing element, enabling the construction of highly sensitive and precise sensor systems.
4. Dense Wavelength Division Multiplexing (DWDM) Systems: Circulators are utilized in DWDM systems to add or drop channels and to separate signal directions, thus improving channel isolation and reducing cross-talk.
5. Optical Add-Drop Multiplexers (OADMs): Circulators are crucial in OADMs for adding or dropping specific wavelength channels from the fiber, which is essential in managing bandwidth and routing in optical networks.
6. Biomedical Imaging and Laser Surgery: In medical applications, circulators are used to manage light delivery and collection, enhancing the precision and effectiveness of procedures like laser surgery and biomedical imaging.
7. Test and Measurement Instruments: Circulators are often used in optical test equipment to separate the source and detector paths, improving the accuracy and reliability of measurements.
8. Optical Coherent Tomography (OCT): In OCT systems, used for high-resolution imaging, circulators are used to direct light into the tissue and then to the detector after reflection, enhancing image clarity and depth.
Q:What does Operating Wavelength Range do?
A:The Operating Wavelength Range of a device or system, especially in the context of optical and photonic systems, refers to the range of wavelengths over which the device or system can effectively operate or perform its function with acceptable efficiency and performance. This term is crucial in various fields, including telecommunications, fiber optics, laser systems.
1. Fiber Optic Communications: In fiber optics, the operating wavelength range specifies the range of light wavelengths over which the fiber exhibits acceptable signal attenuation and dispersion characteristics. This is vital because certain types of optical fiber are optimized for specific wavelength ranges, such as the 1550 nm range for long-distance communication in single-mode fibers.
2. Optical Filters and Coatings: For optical filters (like bandpass, longpass, shortpass) and coatings (like anti-reflective coatings), the operating wavelength range indicates the range of wavelengths over which the filter or coating meets its specified performance. For instance, a bandpass filter might be designed to transmit light only within a narrow wavelength range while blocking or reflecting wavelengths outside that range.
3. Laser Systems: Lasers have a specific operating wavelength range that indicates the range of wavelengths they can emit. This range is determined by the laser medium (like Nd:YAG, CO2, or semiconductor materials) and the laser cavity design. The operating wavelength is crucial for applications like cutting, engraving, medical treatments, and scientific research.
4. Sensors and Detectors: For sensors and detectors, the operating wavelength range specifies the range of wavelengths the device can detect or measure effectively. For instance, some photodetectors are designed to be sensitive to a specific portion of the electromagnetic spectrum, such as infrared, visible, or ultraviolet light.
Q:What does Insertion loss mean?
A:Insertion loss refers to the loss of signal power resulting from the insertion of a device in a transmission line or optical fiber and is usually expressed in decibels (dB). When a signal passes through any electronic device or a transmission medium, some of its power is lost due to various reasons like absorption, scattering, reflection, and material imperfections.
In the context of electronics and signal processing, insertion loss measures how much the signal has weakened after passing through a filter, cable, connector, or other network component. A lower insertion loss implies that the device has a better performance, meaning it allows more of the signal to pass through with less attenuation.
In the context of optical fibers and systems, insertion loss can refer to the loss of signal power resulting from the insertion of components such as connectors, splices, and fiber length.
It's important in system design and testing to ensure that the total insertion loss does not exceed a certain level to maintain the quality and integrity of the signal or to meet power budget requirements.
Q:What is Extinction Ratio?A:The Extinction Ratio is a term commonly used in the fields of optics and telecommunications, especially when discussing the performance of optical components like modulators and switches, as well as in fiber optic communications. It is a measure of the effectiveness of a device in distinguishing between its "on" (light) and "off" (dark) states. Here's a more detailed explanation:
1.In Optical Communications: Extinction Ratio pertains to the ratio of the optical power output when the light source is on (Pon) to the optical power output when the light source is off (Poff). It's usually expressed in decibels (dB) and can be calculated using the formula:A higher extinction ratio indicates a clearer distinction between the on and off states, leading to less ambiguity in signal interpretation, reduced error rates, and overall better performance in digital communication systems.
2. In Optical Components: For components like modulators, which are used to encode information onto a light beam, the extinction ratio measures the contrast between the maximum and minimum optical power levels (representing digital '1' and '0', respectively). In this context, a high extinction ratio is crucial for maintaining signal integrity, as it ensures that the '1's and '0's are distinctly recognizable by the receiving end of the communication system.
3. Importance in System Performance: The extinction ratio is an important parameter in digital optical communication systems because it affects the bit error rate (BER). A low extinction ratio can lead to higher bit error rates as the receiver might find it difficult to distinguish between the '1' and '0' states. Therefore, maintaining a high extinction ratio is essential for the reliability and efficiency of optical communication systems.
In summary, the extinction ratio is a key performance metric in optical systems, indicating the ability of a device to clearly differentiate between its on and off states, which is crucial for the accuracy and reliability of data transmission in fiber optic networks.
Q:What is Return Loss (input/output)?
A: Return Loss, in the context of telecommunications and signal transmission, refers to the measure of power reflected or lost when a signal is transmitted into a device or transmission line. It's a parameter used to describe how well a device or a line is matched to the source impedance. Return Loss can be considered for both input and output of a device:
1. Input Return Loss: This refers to the power that is reflected back towards the source when a signal encounters a device or a transmission line. This reflection usually occurs due to impedance mismatches at the input of the device or line. A high Input Return Loss value is desirable as it indicates a low amount of power is being reflected and, consequently, a better impedance match.
2. Output Return Loss: Similarly, this refers to the power that is reflected back into a device or transmission line at its output. It's an indication of how well the output of the device or line is matched to the load impedance it's driving. As with Input Return Loss, a higher Output Return Loss value is preferable as it signifies a low level of reflected power and a good impedance match.
Return Loss is usually expressed in decibels (dB) and can be calculated using the formula:
or, equivalently,
Here, Pincident is the power of the incident (incoming) signal, and Preflected is the power of the signal that is reflected back.
Q:What does Polarization Dependent Loss mean?
A:Polarization Dependent Loss (PDL) is a key parameter in the field of optics, particularly in fiber optic communications and photonic systems. It refers to the variation in the loss of a light signal due to the polarization state of the light. In essence, PDL measures the difference in transmission loss between the most and the least transmitted polarization states through an optical component or a fiber.
Here's a breakdown of the concept:
1. Polarization of Light: Light is an electromagnetic wave, and polarization describes the orientation of the electric field vector of the light wave. In fiber optics, light can have different polarization states, such as linear, circular, or elliptical polarization.
2. Dependence of Loss on Polarization: Ideally, an optical component (like a fiber, coupler, or filter) should treat all polarization states the same. However, imperfections, asymmetries, or design specifics can lead to different losses for different polarization states. This discrepancy is what we refer to as Polarization Dependent Loss.
3. Impact in Optical Systems: PDL is particularly significant in systems where the polarization state can vary or is not well controlled. High PDL can lead to signal degradation, especially in systems that rely on consistent transmission characteristics, such as dense wavelength division multiplexing (DWDM) systems.
4. Quantifying PDL: PDL is typically expressed in decibels (dB) and is calculated as the difference in transmission loss between the polarization state that experiences the highest loss and the state that experiences the lowest loss:
where L-max is the loss at the polarization state with the maximum loss, and L-min is the loss at the polarization state with the minimum loss.
5. Managing PDL: In high-performance optical systems, managing and minimizing PDL is crucial. This can involve careful component selection, precise control of the manufacturing process, and the use of polarization-maintaining fibers or polarization diversity schemes.
In summary, PDL is an important factor in the performance of optical systems. It indicates how sensitive an optical component or system is to the polarization state of the light, and a high PDL can adversely affect system performance, especially in applications requiring high precision or in systems where the state of polarization can vary unpredictably.
Q:What is Cross Talk?
A:Cross Talk in telecommunications and signal processing refers to any phenomenon by which a signal transmitted on one channel or path creates an undesired effect in another channel or path. Essentially, it's interference from one communication line impacting another, leading to degraded signal quality and potential loss of information. Cross Talk can occur in various forms and contexts:
1. Electrical Cross Talk: In electrical circuits, especially in densely packed circuits like those on a motherboard or within a multi-core cable, signals in one circuit or channel can induce unwanted signals in adjacent circuits or channels, primarily due to electromagnetic coupling.
2. Optical Cross Talk: In fiber-optic communications, cross talk occurs when the signal from one fiber or channel leaks into another, often due to imperfect isolation between channels or components like multiplexers and switches.
3. Wireless Cross Talk: In wireless communication systems, cross talk can occur when signals from one transmission interfere with another, often due to overlapping frequencies or insufficient isolation between antennas.
Q:What is Tensile Load?
A:Tensile Load refers to the force or load that is applied to a material or structure in a way that tends to stretch or elongate it. This concept is fundamental in the field of materials science and structural engineering, where understanding how materials behave under different types of loads is crucial for design and safety.
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