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)
More
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)
傅里叶变换光谱仪(900-16000nm)
高光谱相机 (220nm-4.2μm)
多光谱相机 (400-1000nm)
单光子探测器(SPD)(200-1700nm)
光电倍增管 (PMTs)
光电二极管(PD)(200nm-12um)
热电红外探测器(2-12um)
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)
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(4-17um)
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
SIMSCOP工业线扫共聚焦显微镜L系列
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
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
自由声光可调滤波器 (AOTF)
光纤耦合声光可调滤波器
声光Q开关 (AOQ)
声光频移 (AOFS)
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
X-XY电动载物台
X-XYZ电动载物台
X-XYM线性电动显微载物台
X-FWR 电动滤光片转盘
Polarization Maintaining Coarse WDM (CWDM) stands out for its low insertion loss and high return loss, ensuring signal quality and reliability. It's designed for stability in CWDM systems, modules, and networks, with a wide transmission width facilitating efficient data transmission. Ideal for robust and high-capacity network infrastructures.
Features
Applications
Specifications
Parameters
Unit
Values
Center Wavelength
nm
ITU or ITU+1
Operating Wavelength
1260~1460 or 1460~1620 or 1260~1620
Channel Space
20
Min. Channel Bandwidth @λc
±6.5
Max. Channel Flatness
0.4
Max. Insertion Loss at 23℃
Transmission Channel
dB
0.6
Reflection Channel
0.4 (1260~1460 or 1460~1620) or 0.6 (1260~1620)
Min. Isolation at 23℃
Adjacent Channel
30
Non-adjacent Channel
40
12
Min. Return Loss
50
Min. Extinction Ratio at 23℃
Max. Wavelength Thermal Stability
nm/℃
0.003
Max. Insertion Loss Thermal Stability
dB/℃
0.005
Max. Power Handling (CW)
mW
500
Operating Temperature
℃
0~+70
Storage Temperature
-40~+85
With connectors, IL is 0.3dB higher, RL is 5dB lower, and ER is 2dB lower.
Connector key is aligned to slow axis.
Package Dimensions
Ordering Information
STPMCWDM-①①-②③④-⑤⑤⑤-⑥⑦-⑧-⑨⑨⑨
①①
- Center Wavelength:
27=1270nm or 1271nm, ..., 61=1610nm or 1611nm, SS=Specified
②
- Operating Wavelength:
F=Full wave (1260nm~1620nm), H=Half wave (1260~1460 or 1460~1620)
③
- Port Type:
3=1x2
④
- Working axis for Signal:
B=Both axis working, F=Fast axis blocked
⑤⑤⑤
- Fiber Type:
001=PM1550, 002=PM1310, SSS=Specified
⑥
- Package Dimensions:
0=φ5.5x35mm, S=Specified
⑦
- Pigtail Type:
0=250μm bare fiber, 1=900μm loose tube
⑧
- Fiber Length:
0.8=0.8m, 1.0=1m, S=Specified
⑨⑨⑨
- Connector Type:
0=FC/UPC, 1=FC/APC, 2=SC/UPC, 3=SC/APC, N=None, S=Specified
Q:What is WDM/DWDM/CWDM/Bandpass Filter and what their use for?
A:WDM (Wavelength Division Multiplexing), DWDM (Dense Wavelength Division Multiplexing), CWDM (Coarse Wavelength Division Multiplexing), and Bandpass Filters are technologies used in the field of fiber-optic communications. They are designed to increase the amount of data that can be transmitted over a single fiber by utilizing different wavelengths (colors) of light. Here's a breakdown of each technology and its use:
WDM (Wavelength Division Multiplexing):Description: WDM is a technology that combines multiple optical carrier signals on a single optical fiber by using different wavelengths of laser light. This technique enables bidirectional communications over one strand of fiber, as well as multiplication of capacity.
Use: It's used to increase bandwidth over existing fiber networks. WDM systems are divided into two types: DWDM and CWDM.
DWDM (Dense Wavelength Division Multiplexing):Description: DWDM is a version of WDM that uses closely spaced wavelengths. It's called "dense" because the wavelength channels are very narrow and close to each other. DWDM can support up to 80 (and sometimes more) channels and can transmit data rates of 10 Gbps, 40 Gbps, and 100 Gbps per wavelength.
Use: It's primarily used in large-scale telecommunications networks to increase bandwidth and support long-haul transmission. It's capable of carrying large amounts of data across intercontinental distances.
CWDM (Coarse Wavelength Division Multiplexing):Description: CWDM is a more cost-effective version of WDM. It uses fewer and more widely spaced wavelengths. It typically supports up to 18 channels and doesn't require the expensive cooling systems that DWDM systems do.
Use: It's ideal for short-range communications, so it's used in metropolitan area networks (MANs) where the distances between network nodes are relatively short. It's less expensive than DWDM and used where less capacity is needed.
Bandpass Filter:Description: A bandpass filter is a device that passes frequencies within a certain range and rejects (attenuates) frequencies outside that range. In the context of WDM systems, optical bandpass filters are used to selectively transmit a desired wavelength or a range of wavelengths.
Use: They are used within WDM, DWDM, and CWDM systems to separate or combine different wavelengths of light efficiently. For example, they can extract a single channel from a multi-wavelength signal or combine multiple channels into a single fiber.
In summary, WDM, DWDM, and CWDM are technologies used to multiply the data capacity of fiber-optic cables by carrying multiple channels, each on its own separate light wavelength. Bandpass filters are essential components in these systems, allowing for the precise separation and combination of these channels. These technologies and components enable the high-speed, high-capacity data transmission required by modern telecommunications networks, internet infrastructure, and various data-intensive applications.
Q:What is Transmission Wavelength?A:Transmission wavelength refers to the distance over which a wave's shape (its form and amplitude) repeats itself in the context of electromagnetic waves, such as those used in radio, television, and data communication. It's a crucial concept in various fields, including telecommunications, physics, and engineering. Here are some key points to understand about transmission wavelength:
1.Definition: The wavelength of a signal is the distance between two consecutive points that are in phase. This means points that have the same displacement and motion relative to a medium, like two consecutive crests or troughs of a wave.
2.Relation to Frequency: Wavelength(λ) is inversely proportional to the frequency(ƒ)of the wave, and this relationship is described by the equation λ=V/ƒ, where V is the speed of the wave through the medium. For electromagnetic waves in a vacuum, V is the speed of light (approximately 3X108meters per second).
The chart above illustrates the relationship between frequency and wavelength for electromagnetic waves, based on the equation λ=c/ƒ, where λ is the wavelength c is the speed of light, and ƒ is the frequency.
3. Spectrum and Applications: Different wavelengths (and therefore frequencies) are used for different types of communications. For instance:
- Radio waves can have very long wavelengths (from 1 meter to 1000 meters or more), suitable for broadcasting over long distances.
- Microwaves have shorter wavelengths and are used for point-to-point communication systems and for satellite communications.
- Infrared, visible light, and ultraviolet light have even shorter wavelengths and are used in various applications, including fiber-optic communication, where data is transmitted over long distances at high speeds.
4. Bandwidth and Data Capacity: In optical communications (like fiber optics), the transmission wavelength is crucial because different wavelengths can be used simultaneously to carry different signals, a technique known as Wavelength-Division Multiplexing (WDM). This significantly increases the capacity of a system to carry data.
5.Propagation Characteristics: The wavelength of a signal also affects its propagation characteristics, like how it interacts with different materials, how it is absorbed, and how it reflects or refracts. This is why different wavelengths are used for different applications; for example, certain wavelengths are better for underwater communication, while others are better for open-air or space communications.
In summary, the transmission wavelength is a fundamental property of waves that impacts how signals are transmitted, received, and processed in various communication systems. It's closely tied to the frequency of the signal and determines many of the signal's propagation and interaction characteristics.
Q:What is Reflection Wavelength?A:Reflection Wavelength is the specific wavelength or range of wavelengths that are reflected by a medium or device, like a mirror or a filter, while other wavelengths pass through or are absorbed. This property is crucial in optical applications to control and manipulate light paths, enhancing the performance of systems such as sensors, lasers, and communication networks.
Q:What is Channel Bandwidth?
A:Channel bandwidth refers to the range of frequencies that a communication channel can transmit. It is a key concept in telecommunications and signal processing, representing the capacity of a channel to carry information.
The chart above visualizes the concept of channel bandwidth. In this example:The bandwidth of the channel is represented as the range of frequencies between 20 kHz and 40 kHz, giving a total bandwidth of 20 kHz.The area shaded in light blue indicates the range of frequencies that the channel can carry.The signal presence is indicated by the height of the blue area; it's either present (1) or not present (0), representing a simple on/off signal for illustrative purposes.
The concept can be better understood through a few key points:
Frequency Range: Bandwidth is often measured as the difference between the highest and the lowest frequencies in a continuous set of frequencies. For instance, if a channel can carry signals with frequencies from 20 Hz to 20 kHz, its bandwidth is 20 kHz - 20 Hz = 19.98 kHz.
Data Transmission Rate: In digital communications, the bandwidth of a channel is related to the rate of data transmission. According to the Nyquist theorem, the maximum data rate (in bits per second) that can be transmitted over a noiseless channel is twice the bandwidth of the channel (in Hz), assuming each signal change (baud) carries one bit of information.
Signal Processing: In signal processing, bandwidth is the width of the range of frequencies that an electronic signal occupies on a given transmission medium. Different signals (like radio, TV, and internet data) require different bandwidths.
Network Performance: In networking, bandwidth is often used to refer to the capacity of a network connection, though it's technically different from speed. Bandwidth indicates the maximum amount of data that can be transferred over a network path in a fixed amount of time, usually measured in megabits per second (Mbps) or gigabits per second (Gbps).
Bandwidth Limitations: The bandwidth of a channel can be affected by various factors, including the medium's physical properties (like fiber optics vs. copper), signal interference, and the technology used in transmission and reception.
Understanding channel bandwidth is crucial for designing and managing communication systems, as it directly impacts the quantity and quality of information that can be transmitted over a channel.
Q:What does Channel Flatness mean?
A:Channel flatness refers to a measure of how uniformly a communication channel or system transmits different frequencies within a specified bandwidth. It's an important characteristic in many communication systems, especially those dealing with a wide range of frequencies, like RF (radio frequency) communication systems, audio systems, and certain wireless communication technologies.
Here's what you need to know about channel flatness:
Uniformity of Response: Channel flatness is essentially about how consistently a channel or system transmits signals across its entire frequency range. A perfectly flat channel would transmit all frequencies with equal power, meaning the channel does not preferentially attenuate or amplify any frequency within its operational bandwidth.
Measurement and Representation: Channel flatness is usually measured in decibels (dB) and often graphed as a frequency response curve, showing the gain or loss of the system at different frequencies. A completely flat curve would indicate perfect channel flatness.
Impact on Performance: Non-uniformities or peaks and dips in the channel's frequency response can lead to various issues, such as distortion of the signal, unequal signal strength at different frequencies, or certain frequencies being lost or attenuated. In data communication, this can result in data loss or the need for additional error correction and compensation measures.
In Audio Systems: In audio systems, channel flatness is crucial for sound quality. A non-flat response can color the sound, leading to an inaccurate reproduction of the audio signal. For high-fidelity audio systems, a flat response is often desired to ensure that all frequencies are equally represented.
In RF and Wireless Communications: For RF and wireless systems, channel flatness is important for ensuring that all parts of the signal spectrum are transmitted with equal strength. This is particularly important in systems using complex modulation schemes or multiple frequency bands, where non-uniformities can lead to interference or data loss.
Challenges and Compensations: Achieving perfect channel flatness is challenging due to physical limitations, component imperfections, and environmental factors. Therefore, systems often incorporate equalization and filtering techniques to compensate for known non-uniformities in the channel response.
In summary, channel flatness is a measure of the consistency with which a channel transmits different frequencies. It's an important parameter in the design and assessment of many types of communication systems, impacting the fidelity and efficiency of signal transmission.
Q:What does Power Handling (CW) use for?A:Power Handling(CW), in the context of optical components, refers to the maximum continuous optical power that a device can handle or operate under without degrading its performance or reliability. It's essential for ensuring the longevity and stability of optical devices in systems where they are exposed to continuous light sources, such as in telecommunications or laser applications.
Q:What does Transmission Isolation mean?A:Transmission Isolation in the context of filters (like WDM, DWDM, CWDM) refers to the ability of the filter to prevent or significantly attenuate unwanted wavelengths or signals from passing through while allowing the desired wavelength range to transmit. This ensures that only the targeted signals are transmitted, enhancing the clarity and quality of the communication channel or system.
High Power Polarization Maintaining Fused WDM
(up to 20W)
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公司
光谱分析
显微镜
光源和激光
成像相机
光学元件