SR400光子计数器

光子计数器的工作原理光子计数器是一种能够测量光子数量的仪器，它利用光学探测技术和电子计数技术来实现。

它的原理可以分为三个步骤：光子的探测、光电转换和电子计数。

首先，光子计数器通过一个光学系统将待测的光束引入到光子计数器中。

这个光学系统通常由一个窗口、一个滤波器和一个光导纤维等组成。

窗口用于防止污染和干扰，滤波器用于选择特定波长或频率的光线，光导纤维用于传输光子到光子计数器。

这样，光子计数器可以接收到一个特定波长或频率的光束。

接下来，光子计数器中的光子会经过光电转换器。

光电转换器是光子计数器的核心部件，其作用是将光子转化为电信号。

光电转换器通常采用光敏材料或光电二极管。

当光子经过光电转换器时，光子的能量被转化为电子能量，产生一对电子-空穴对。

这对电子-空穴对会在电场的作用下分离形成电信号。

光电转换器产生的电信号大小与光子的能量成正比，通过测量电信号的强度，可以确定光子的数量。

最后，光子计数器会将电信号输入到电子计数器进行处理和记录。

电子计数器是光子计数器的另一个核心部件，其作用是将电信号转化为数字信号，并统计信号的数量。

电子计数器通常由一个放大器、一个单光子探测器和一个计数器组成。

放大器用于放大电信号的强度，使其达到单光子探测器的检测灵敏度。

单光子探测器可以准确地检测到每一个光子的到达，并产生相应的电信号。

计数器用于记录每一个光子的到达，并根据光子的数量进行计数。

通过对计数器进行机械或电子的计数，可以得到光子的数量。

光子计数器的工作原理基于光的粒子性质和电的波动性质。

根据光的粒子性质，光被看作是由一系列离散的光子组成的，并且每个光子具有特定的能量。

根据电的波动性质，光可以被看作是一种电磁波，波的振幅决定光的强度。

光子计数器利用了光子的粒子性质实现了光子的探测和光电转换，利用了光的波动性质实现了电子计数和数据记录。

光子计数器具有高精度、高可靠性和高灵敏度等特点，广泛应用于光子学、量子物理学、光通信等领域。

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芯片内置高精度校准模块，对传感器的失调误差和增益误差进行精确补偿。

±2G、±4G、±8G和±16G四种可调整的全量程测量范围，灵活测量外部加速度，输出数据率1HZ和400HZ间可选。

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芯片内置产品倾斜校准功能，对贴片和板卡安装导致的倾斜进行补偿，不占系统资源，系统文件升级不影响传感器参数。

主要特点宽电压范围1.71V-3.6V1.8V兼容数字IO口低功耗模式下电源电流低至2µA±2G/±4G/±8G/±16G动态全量程范围 12bit有效数据(HR)I²C/SPI数字输出接口6D/4D方向检测自由落体检测单击双击检测及运动检测可编程中断生成电路内嵌自测试功能内嵌FIFO10000g高G抗击能力应用手机平板室内导航图像旋转运动激活用户接口游戏产品规格分类产品名称 封装形式 打印名称 材料 包装形式 SC7A20TR LGA-12-2x2x1.0 SC7A20 无铅编带内部框图XY ZC-to-V Converter Gain数符号测试条件最小值V CC电路不损坏-0.3 3.6V P电路不损坏V in电路不损坏T OPR电路不损坏T STG电路不损坏(VDD=2.5V, T测试条件123FS=0 (HR mode)FS=1 (HR mode)FS=2 (HR mode)FS=3 (HR mode)参 数符 号测试条件最小值 典型值 最大值 单位 零漂 Ty Off0 FS =0 --±40--mg温漂TC Off 与25°C 的最大偏差 -- ±0.5 -- mg/°C 自测输出V st1FS=0， X 轴 -- 276 -- LSb V st2 FS=0， Y 轴 -- 276 -- LSb V st3FS=0， Z 轴-- 984 -- LSb 系统带宽 BW -- ODR/2 -- HZ 工作温度T OPR-40--+85°C注意：电路2.5V 出厂校准。

单光子计数器工作原理引言：单光子计数器（Single Photon Counter）是一种用于检测光子的仪器，它可以用于量子通信、光学成像、光谱测量等领域。

单光子计数器的工作原理涉及到光子的检测、计数和信号处理等多个方面。

本文将从光子的产生到信号的处理，全面解析单光子计数器的工作原理。

一、光子的产生光子是光的量子，它是电磁辐射的最小单位。

在实验室中，光子可以被产生出来，常见的方法有以下几种：1.激光激光是一种被高度定向和集中的光。

光子产生于激光器的激光管或半导体激光器中，激光器可以产生连续光束或脉冲光束，其光子的数量和频率可以被精确控制。

2.荧光材料某些材料被激发后会发出荧光，这时会产生光子。

这类材料通常作为素材，用于实验室中的荧光探测器和成像设备中。

3.放射性材料放射性材料产生的放射性衰变会导致光子的发射，这种放射性光子可以被用于核辐射测量和研究。

二、光子的检测单光子计数器的核心部分是光子检测器，它可以将入射的光子转换为可测量的电信号。

常用的光子检测器包括光电二极管（Photomultiplier Tube，PMT）、光电二极管（Avalanche Photodiode，APD）和超导单光子检测器（Superconducting Single Photon Detector，SSPD）等。

这些光子检测器各有特点，但它们的工作原理可以归纳为光电效应或光生电子效应。

1.光电效应在PMT中，光子进入光阴极后，会激发光电子的产生。

而在APD中，光子进入硅片后，会将成对的电子-空穴对分离，并通过增倍载流子的方法得到可测量的电流。

这两种方式都是通过光电效应将光子转化为电信号。

2.光生电子效应SSPD采用超导材料，在光子入射后会导致超导态的破坏，引发电子的产生。

这种方式也是将光子转化为电信号的方式之一。

三、光子的计数光子计数是单光子计数器的关键功能之一。

它可以通过对间歇光源的光子进行计数，从而实现对光子的精确计量。

第24卷第3期大学物理实验Vol.24No.32011年6月PH Y SICA L EXPERI M ENT OF CO L LEG EJun.2011收稿日期:2011 01 25文章编号:1007 2934(2011)03 0023 03用单光子计数系统检测微弱光信号吴丽君(沈阳理工大学,辽宁沈阳 110159)摘要:阐述了单光子计数实验中采用脉冲幅度甄别器和光子计数器测量光子数的实验原理,绘制了不同光照时间下的实验曲线,讨论了可能影响实验测量精度及产生误差的原因。

关键词:单光子计数;光功率中图分类号:G424 3文献标志码:A光子计数技术,是检测极微弱光的有力手段,这一技术是通过分辨单个光子在检测器(光电倍增管)中激发出来的光电子脉冲,把光信号从热噪声中以数字化的方式提取出来。

这种系统具有良好的长时间稳定性和很高的探测灵敏度。

目前,光子技术系统广泛应用于科技领域中的极微弱光学现象的研究和某些工业部分中的分析测量工作,如在天文测光、大气测污、分子生物学、超高分辨率光谱学、非线性光学等现代科学技术领域中,都涉及极微弱光信息的检测问题。

1实验原理1.1光子流量和光流强度光是由光子组成的光子流,光子是一种没有静止质量,但有能量(动量)的粒子。

一个频率为v(或波长为 )的光子,其能量为E F =hv =hc/ (1)式中普朗克常量,h =6.6 1034(Jg S),一束单色光的功率等于光子流量乘以光子能量,即P =RgE p (2)光子的流量R (光子个数/S )为单位时间内通过某一截面的光子数,如果设法测出入射光子的流量R,就可以计算出相应的入射光功率P 。

有了一个光子能量的概念,就对微弱光的量级有了明显的认识,例如,对于氦 氖激光器而言,1m W 的光功率并不是弱光范畴,因为光功率P =1mW ,则R =P E p=3.2 1015光子/S所以,1mW 的氦 氖激光,每秒有1015量级的光子,从光子计数的角度看,如此大量的光子数是很强的光子。

光子美容机控制软件（触摸屏）操作说明1．欢迎界面开启设备总电源开关，屏幕显示欢迎界面，如图一所示，大约2秒钟后自动进入治疗模式选择界面。

（图一）2．选择治疗模式界面系统时钟或水温提示区选择治疗模式（图二）进入治疗模式选择界面后，如图二所示。

点选相应的治疗键即可选择脱毛治疗或嫩肤治疗工作模式，点选“设置”键可进入系统功能参数设定界面，可修改系统的功能选项。

3．治疗界面光头计数治疗记录水温显示治疗参数系统提示光头状态输出能量显示窗口（图四）进入治疗界面，如图四所示，在治疗界面中，我们可以进行治疗参数的调整。

按“开始”键触发光头并给电容自动充电，系统提示区显示“充电中…”，当充电完成后即可进行治疗。

按“停止”可关闭光头，按“返回”可返回“治疗模式选择菜单”，并关闭光头。

光头状态：显示当前选择的治疗模式及光头的类型；输出能量显示窗口：当前光头输出能量的大小显示；治疗参数：当前治疗模式下记录的治疗参数；系统提示：当前按键的功能提示；光头计数：显示本次治疗的光头发光的次数，点选数字即可清零；水温显示：当前的系统的水温。

治疗记录：显示当前的治疗记录，可以记录不同的治疗参数，已便于治疗不同患者，点选即可更改治疗记录。

修改治疗参数输入键盘窗口提示当前调节内容脉冲参数调节窗口（图五）治疗参数代表的是治疗过程中可以调节的数据，通过调节治疗参数，我们可以改变治疗光头输出的能量，脉宽以及脉冲个数，从而达到不同的治疗效果。

可调整的治疗参数一共有8项（图示见图六）：输出能量：调节光头的输出能量，调节过程中能量显示窗口会显示当前的输出能量值，调节范围0~50J/cm2，此项设置可直接在治疗过程中直接调节，用“△或▽”键调节，“△”键为增加，“▽”键为减少，按住“△或▽”键可快速调节输出能量，如图四所示。

脉冲间隔：调节治疗脉冲的重复频率，调节范围（1~4S）秒，点选即可调整。

脉冲个数：选择治疗脉冲的个数，调节范围（1~6）个，点选即可调整。

激光尘埃粒子计数器URS记录编号:URS-ZL-2013-001记录版号:01 用户需求标准项目名称激光尘埃粒子计数器制药企业净化空调系统是保证药品质量的关键系统之一，而尘埃粒子控制是制药企业净化空调系统中的一个关键指标。

公司对质量部设备进行更综述新，现对激光尘埃粒子计数器进行采购。

执行标准Q/320500VTJ01-2002 法律标准部门职务签名日期起草审核批准URS01:配置要求材质要求:URS01-1 1.光源为半导体激光光源，寿命大于30000小时。

2、显示屏为液晶屏。

自动控制功能:1、 PLC编程控制程序，电压、频率、循环温度、气压等参数实时监控URS01-2 检测保护和警报等功能。

2、液晶显示内容由电脑控制。

3、调节旋钮可任意调节。

URS01-3 应该具有:随机配备品备件及配套资料。

URS01-4 *报价单要有主要配置清单。

URS02:效率要求1记录编号:URS-ZL-2013-001记录版号:01 用户需求标准URS02-1 激光尘埃粒子计数器无故障工作积累时间不得小于8000h， URS02-2 采样流量:?28.3L/min。

URS02-3 满足10~30万级自动判别净化级别。

URS03:流程设计要求URS03-1 需阐述设备工作流程的原理。

URS03-2 必须体现如何对设备过程控制。

URS04: 安全要求URS04-1 材料能承受而不致遭到破坏的最高电场强度。

URS04-2 非安全区贴有警示标志。

设备上易对操作人员造成伤害的运动部位应有安全罩，电气控制柜装URS04-3 有安全锁。

1、距离设备1m的噪音在60分贝以下，具有静电接地和漏电保护等安全防护装置。

2、设备任何部位不能有锋利的边缘和尖角。

URS04-43、设备应优化设计，安装紧急停止按钮，以减少人、机伤害。

安全符合相关安全标准。

URS05:安装区域及位置要求URS05-1 使用在10~30万级洁净区。

URS06:环境要求URS06-1 使用在10~30万级洁净药品生产区。

Features and BenefitsF orce Sensing Resistors®DescriptionInterlink Electronics FSR®400 Series is part of the single z one Force Sensing Resistor®family. Force Sensing Resistors, or FSR's, are robust polymer thick film (PTF) devices thate x hibit a decrease in resistance with increase in force applied to the surface of the sensor. This force sensitivity is optimi z ed for use in human machine interface devices including automotive electronics, medical systems, industrial controls and robotics.The FSR400 Series sensors come in seven different models with four different connecting options. A battery operated demo is available. C all us for more information a t+1 805-484-8855.P/N: PDS-10004-CFSR® 400 Short5mm Circle x 20mmFSR® 4005mm Circle x 38mmFSR® 402 Short13mm Circle x 25mmFSR® 40213mm Circle x 56mmFSR® 40420mm Donut with 5.5mm holdFSR® 40638mm Square x 83mmFSR® 408-xx x10mm Wide x xx x mm stripxx x = 50, 100, 200, 300, 400, 500mm•Actuation f orce as low as 0.2N and sensitivity range to 20N •Cost effective•Ultra thin•Robust; up to 10M actuations •Simple and easy to integrateForce Sensing Resistors ®Specifications are derived from measurements taken at 1000 grams, and are given as (one standard deviation/mean), unless otherwise noted.*Typical value. Force dependent on actuation interface, mechanics, and measurement electronics.Device Characteristics Actuation Force*Force Sensitivity Range*Force ResolutionForce Repeatability Single Part Force Repeatability Part to Part Non-Actuated Resistance Hysteresis Device Rise Time Long Term Drift1kg load, 35 daysOperating Temperature PerformanceCold: -40ºC after 1 hour Hot: +85ºC after 1 hourHot Humid: +85ºC 95RH after 1 hour Storage Temperature PerformanceCold: -25ºC after 120 hours Hot: +85ºC after 120 hoursHot Humid: +85ºC 95RH after 240 hours Tap DurabilityTested to 10 Million actuations, 1kg, 4Hz Standing Load Durability2.5kg for 24 hours EMI ESD UL RoHS~0.2N min ~0.2N – 20N Continuous (analog)+/- 2%+/- 6% (Single Batch)>10 Mohms+10% Average (RF+ - RF-)/RF+< 3 Microseconds < 5% log10(time)-5% average resistance change -15% average resistance change +10% average resistance change -10% average resistance change -%5 average resistance change +30% average resistance change-10% average resistance change-5% average resistance change Generates no EMI Not ESD SensitiveAll materials UL grade 94 V-1 or better CompliantConnector InformationApplication InformationFor specific application needs please contact Interlink Electronics support team. An Integration Guide and Hardware Development Kit (HDK) are also available. FSR's are two-wire devices with a resistance that depends on applied force. Below is a force vs. resistance graph that illustrates a typical FSR ® response characteristic. Please note that the graph values are reference only and actual values are dependent upon actuation system mechanics and sensor geometry.For simple force-to-voltage conversion, the FSR device is tied to a measuring resistor in a voltage divider (see figure below) and the output is described by the following equation.F orce Sensing Resistor ®In the configuration shown , the output voltage increases with increasing force. If R FSR and R M are swapped, the output swing will decrease with increasing force. The measuring resistor, R M , is chose n to maximize the desired force sensitivity range and to limit current. Depending on the impedance requirements of the measuring circuit, the voltage divider could be followed by an op-amp.A family of force vs. V OUT curves is shown on the graph below for a standard FSR in a voltage divider configuration with various R M resistors. A V+ of 5V was used for these examples. Please note that the graph values are for reference only and will vary between different sensors and applications.Refer to the FSR Integration Guide for more integration methods and techniques.F orce Sensing Resistor®Sensor Mechanical DataModel 400:Active Area: Ø5.08mmNominal Thickness: 0.30mmSwitch Travel: 0.05mmAvailable Part Numbers:PN: 34-00007 Model 400-No contacts or solder tabsPN: 34-00011 Model 400-with female contactsPN: 34-44001 Model 400-with female contacts and housingPN: 30-49649 Model 400-with solder tabsExploded ViewForce Sensing Resistor®Exploded ViewSensor Mechanical DataModel 400 Short Tail:Active Area: Ø5.62mmNominal Thickness: 0.30mmSwitch Travel: 0.05mmAvailable Part Numbers:PN: 34-47021 Model 400 Short Tail-No contacts or solder tabsPN: 34-00005 Model 400 Short Tail-with female contactsPN: 34-00006 Model 400 Short Tail-with female contacts and housingPN: 34-00004 Model 400 Short Tail-with solder tabsF orce Sensing Resistor®Model 402:Active Area: Ø14.68mm Nominal Thickness: 0.46mm Switch Travel: 0.15mmAvailable Part Numbers:PN: 44-29103 Model 402-No contacts or solder tabs PN: 34-00012 Model 402-with female contacts PN: 34-00001 Model 402-with female contacts and housing PN: 30-81794 Model 402-with solder tabsExploded ViewSensor Mechanical DataF orce Sensing Resistor®Sensor Mechanical DataModel 402 Short Tail:Active Area: Ø12.70mmNominal Thickness: 0.46mmAvailable Part Numbers:PN: 34-00016 Model 402 Short Tail-No contacts or solder tabsPN: 34-00017 Model 402 Short Tail-with female contactsPN: 34-00018 Model 402 Short Tail-with female contacts and housingPN: 34-00015Model 402 Short Tail-with solder tabsExploded ViewF orce Sensing Resistor ®Model 404 Single Zone Donut:Active Area: Ø4.35mmNominal Thickness: 0.53m m Switch Travel: 0.05mmAvailable Part Numbers:PN: 34-00065 Model 404 Single Zone Donut -with solder tabsExploded ViewSensor Mechanical DataF orce Sensing Resistor®Sensor Mechanical DataModel 406:Active Area: 39.6mm x 39.6mmNominal Thickness: 0.46mmSwitch Travel: 0.15mmAvailable Part Numbers:PN: 34-00009 Model 406-No contacts or solder tabsPN: 34-00013 Model 406-with female contactsPN: 34-61152 Model 406-with female contacts and housingPN: 30-73258Model 406-with solder tabsExploded ViewF orce Sensing Resistor®Model 408:Active Area: XXX mm x 10.2mmNominal Thickness: 0.41mmSwitch Travel: 0.15mmAvailable Part Numbers:PN: 34-00010 Model 408-No contacts or solder tabsPN: 34-75319 Model 408-with female contactsPN: 34-23845 Model 408-with female contacts and housingPN: 30-61710Model 408-with solder tabsPN: 34-00068 Model 408-50-50mm with solder tabsPN: 34-00069 Model 408-100-100mm with solder tabsPN: 34-00070 Model 408-200-200mm with solder tabsPN: 34-00071 Model 408-300-300mm with solder tabs PN: 34-00072 Model 408-400-400mm with solder tabs PN: 34-00073 Model 408-500-500mm with solder tabsContact UsUnited States Corporate Office Interlink Electronics, Inc.31248 Oak Crest DriveSuite 110Westlake Village, CA 91361 USA Phone: +1 (805) 484-8855Fax: +1 (805) 484-9457 Sales&Support:***************Exploded ViewSensor Mechanical Data。

美国Met One 3400 尘埃颗粒计数器（Met One Airborne Particle Counter）型号：3413 3423 3423 3425主要特点1．流量28.3 或50L/min（1.0或1.77cfm）2．最小精度：0.3或0.5微米3．6个粒径通道4．2年整机保修，3年激光二极管保修5．先进的光学设计，更持久的使用寿命6．支持热插拔交换电池，可使用7小时7．大屏幕TFT彩色显示，触摸屏控制8．不锈钢外壳，非污染源设计9．支持USB接口10．PortAll Version 2软件符合制药行业21 CFR Part 11Met One 3400系列空气颗粒计数仪支持大流量采样，操作更方便，能有效减少测量时间。

主机轻便小巧，侧面两只和前面一只的手柄使得携带更为方便。

3400可以垂直放置也可以水平放置。

重要的是，选用两组热插拔交换电池，使得操作连贯。

针对数据的输入和管理，3400提供了彩色高对比度的触摸屏，方便在更远距离不同光线不同视角条件下记录和浏览。

触摸式命令具有直观的图象操作系统，有助于简化计数采集的处理。

通过USB接口和闪存快速传送数据或者利用内置打印机直接打印结果。

基于长寿命的激光技术，3400表现可靠，有利于降低长期的运行成本。

对于无尘室环境所关注的“有机生物污染”问题，3400的不锈钢结构，和平整的表面可通过快速有效的清洁来避免其发生。

3400通过PortAll Version2软件支持21CFR Part11,可遥控定时和数据下载。

此软件可快速产生通过/失败的报告，并提供满足ISO,FDA和EU等规范必须的文件。

技术参数规格：粒径通道（µm）3413和3423：0.3, 0.5, 1.0, 3.0, 5.0, 10.0*3415和3425: 0.5, 1.0, 2.0, 3.0, 5.0, 25.0*流量：3413和3415：28.3L/min(1.0cfm)3423和3425: 50L/min(1.77cfm)零点计数：符合JIS标准。

thermo scientific igs400 说明书1. 产品概述Thermo Scientific IGS400是一款高性能的科学仪器，主要用于测量和监控气体的浓度和组成。

该设备具有精确度高、稳定性好、易于操作等特点，适用于各种实验室和工业环境。

2. 技术规格- 测量范围：根据不同的传感器和模块配置，可以测量多种气体的浓度和组成。

- 精确度：在正常工作条件下，精确度达到0.1%。

- 响应时间：快速响应，通常在几秒钟内完成气体浓度测量。

- 工作温度：适用于-20℃至50℃的环境。

- 通信接口：支持RS232、RS485等多种接口方式，方便与其他设备进行数据交互。

3. 正确使用说明- 安装：将IGS400固定在水平、稳定的台面上，并确保通风良好。

- 连接电源：将设备连接到稳定的电源，并确保电源电压与设备要求相符。

- 接入气体源：根据实际需要，连接气体源管道到设备的进气接口，并保持连接牢固密封。

- 启动设备：打开设备电源，等待设备自检完成后即可开始使用。

- 校准：在初次使用或更换气体传感器后，需要进行校准操作，确保测量结果准确可靠。

4. 功能与操作- 显示屏：设备配备了大屏幕液晶显示屏，可以直观地显示当前测量结果和设备状态。

- 按键操作：设备上设有多个按键，通过按键可以实现各种功能的调节和设置。

- 数据记录：IGS400具备数据记录功能，可以记录并保存测量值，并支持数据导出和打印。

- 报警功能：设备配备了报警系统，当气体浓度超过设定范围时，会发出声音或光信号进行警示。

- 远程监控：通过通信接口，IGS400可以与上位机或其他设备进行连接，实现远程监控和数据传输。

5. 维护与保养- 定期校准：为了保证测量结果的准确性，需要定期进行校准操作。

校准频率的选择应根据实际使用情况和准确度要求进行决定。

- 传感器更换：传感器是设备关键部件之一，如果出现故障或使用寿命到期，需要及时更换。

- 清洁保养：设备的外壳和传感器表面应定期清洁，可以使用干净的软布或棉签轻柔擦拭，避免使用有腐蚀性的溶剂或刷子。

400g SR4指标1. 什么是400g SR4？400g SR4是指一种光纤传输标准，用于高速数据中心和云计算网络中的光纤通信。

它是一种四通道并行传输的光纤标准，每个通道的速率为100Gbps，因此总的传输速率为400Gbps。

2. 400g SR4的指标2.1 传输速率400g SR4的传输速率为400Gbps，这意味着它可以在短距离内以非常高的速度传输数据。

这对于需要大量数据传输的应用程序非常重要，例如高性能计算、大数据分析和人工智能。

2.2 传输距离400g SR4的传输距离受到光纤的类型和质量的限制，一般来说，它的传输距离在100米左右。

这意味着它适用于数据中心内部的短距离通信，但对于长距离通信来说并不适用。

2.3 光纤类型400g SR4使用多模光纤进行传输，这种光纤可以传输多个光束，每个光束被称为一个通道。

在400g SR4中，有四个通道，每个通道的速率为100Gbps。

2.4 光纤接口400g SR4使用MPO接口进行连接，MPO是一种多光束光纤连接器，可以同时连接多个光纤。

这种接口可以提供高速、高密度的光纤连接，非常适合于数据中心和云计算网络中的高密度光纤布线。

2.5 光纤编码400g SR4使用64B/66B编码来实现数据的传输，这种编码可以提高数据传输的可靠性和效率。

它将每个64位的数据块编码为66位的数据块，并在接收端进行解码。

3. 400g SR4的应用400g SR4广泛应用于数据中心和云计算网络中的高速数据传输。

它可以用于连接服务器、存储设备、交换机等网络设备，实现高速、可靠的数据通信。

3.1 数据中心在大型数据中心中，需要快速传输大量的数据，以支持各种应用程序的运行。

400g SR4可以提供高达400Gbps的传输速率，满足数据中心对高速数据传输的需求。

它可以用于连接服务器、存储设备和网络设备，实现数据中心内部的快速数据交换。

3.2 云计算网络在云计算网络中，需要高速数据传输来支持虚拟机的迁移、数据备份和恢复等操作。

SPCM-AQRHSingle Photon Counting ModuleExcelitas Technologies’ recently-improved SPCM-AQRH Single Photon Counting Module detects single photons over the wavelength range of 400nm to 1060nm with performance parameters superior to other solid state or vacuum-tube based photon counters.The SPCM-AQRH uses a unique silicon avalanche photodiode (SLiK) with a circular active area, achieving peak photon detection efficiency greater than 70% at 650nm over a 180µm diameter with unmatched uniformity over the full active area. A TTL-level pulse is generated for each photon detected and the signal is available at the BNC connector at the rear of the module. The signal must be terminated into 50Ω.The photodiode is both thermoelectrically cooled and temperature controlled, ensuring stabilized performance despite ambient temperature changes. Operating temperature range has been increased and the module (case temperature) will function between 5˚C and 70˚C.The module comes with free space window, FC fiber adaptor, C-mount or tube cage mount bracket/adaptor options.Recent electronic circuit improvements have reduced the minimum dead time to less than 25ns, thereby increasing linearity and improving the dynamic range of the module. Timing resolution of the module was also improved significantly. The SPCM-AQRH has internal protection circuitry that protects the avalanche photodiode and the module electronics from damage due to accidental overload from exposure to ambient lighting.Excelitas’ series of photon counting modules are designed and built to be fully compliant with the European Union’s RoHS Directive 2015/863/EU.Key Features∙ Peak PDE: > 70% @ 650nm ∙ 180µm active area∙ > 35 Mcps dynamic range ∙ Gated output ∙ Single +5 V supply ∙ RoHS-compliant∙ Low after pulse probability ∙ High uniformity over large active area∙ Unmatched linearity∙Free space window, FC fiber adaptor, C-mount bracket, Tube cage mount bracket optionsApplications∙ LIDAR∙ Quantum Cryptography ∙ Photon correlation spectroscopy∙ Astronomical observation ∙ Optical range finding ∙ Adaptive optics∙ Ultra-sensitive fluorescence ∙ Particle sizing ∙MicroscopySPCM with free space window (right) and with FC adaptor (left), for tube cage mount bracket and C-mount bracket see page 11Table 1. Specifications of SPCM-AQRH-WX, @ 22°C, all models, unless otherwise indicatedOperating Instructions1.Connection to incorrect voltage or reverse voltage may damage or destroy the module. The warranty is invalid should such damage occur. The center contact of the barrel type power connector (corresponding to the white stripe on the wire) is +5V.2.These modules are not qualified for shock or vibration other than normal instrumentation environments.3.The module dissipates a mean power of 2.0W and a maximum power of 6W at high count rate and 70°C. Adequate heat sinking must be provided by clamping the module to a suitable heat sink via the holes in the module base. To meet specified performance, the module case temperature must not exceed 70°C. See Figure 6 for stability of probability of detection vs. temperature.4.On a small percentage of delivered modules, bi-stability of the dark count has been observed. Research indicates this bi-stability is probably due to transitions at a single impurity site between a low energy and a high energy state.The phenomenon is seen as an abrupt change in the dark count rate, e.g., 350 to 390 c/s., and the dark count switches between the two states at a rate dependent upon the detector temperature. Multilevel switching has also been observed, where more than one impurity site is switching.Long-term bi-stability is related to fundamental semiconductor physics and is beyond Excelitas’ control. Warranty claims will not be considered against bi-stability alone.Warranty claims will only be considered if the high level of the dark count exceeds the maximum level in the specification.5. In the dark, the module generates random counts that follow a Poisson distribution. In a Poissonian process, the standard deviation is equal to the square root of the average count. In this specification the “dark count variation” refers to the stability of the average count of the module.6.The actual photon rate could be calculated using the following equation, as indicated in Note #6 in the box below. This parameter applies to the modules with dark counts of 100cps or higher.Note # 6: Actual photon rate calculation7. For the typical dead time setting of 22ns, typical maximum count rate is 37Mc/s before saturation. If the longest output pulse width option is set (28ns), the typical maximum count rate is 30Mc/s before saturation. If the maximum dead time setting is used, about 62ns, typical maximum count rate would be about 12Mc/s. Note that using a longer dead time will degrade linearity.8.Output pulse width is set at the standard of 10ns ± 2ns at 2.2V. Other output pulse widths can be set. Please refer to Table 3, Ordering Guide, for which model number to order.9.Output pulse height standard is set to 2.2V ± 0.4V. Optional output pulse height is 4.4V. Please refer to Table 3a, Ordering Guide, for which model number to order.10.If needed, an FC fibre adaptor can be factory installed on the SPCM-AQRH module allowing optical fibres to be used. The FC adaptor is optimized for use at 550 nm and with a 100µm core multimode fibre. If other wavelengths or fibre sizes are needed, please contact the factory for availability. The addition of an FC adaptor will cause a small drop in the effective PDE of the module. The amount of the loss will depend on the wavelength and the diameter of the fibre used to provide optical input to the module. Typically, one can expect around a 5% loss with a 100µm core fibre at 550nm.11.Red-NIR wavelength photon detection efficiency can be optimized. PDE is enhanced over the 700-900nm wavelength range. Please refer to the Product Brief of the SPCM-NIR series. See Figure 4 for the typical photon efficiency of standard and enhanced PDE modules.12. Timing resolution is measured using a 10µm diameter light spot, at 825nm, and with case temperature at 22°C. For timing resolution requirements of larger spot size measurement, or at different wavelengths, please contact Excelitas. For timing resolution optimized modules, please refer to the Product Brief of the SPCM-AQRH-TR series13. Afterpulse is measured for the first 500ns (excluding the first 75ns) on the timeline of the afterpulse curve, at an average count rate of 100kc/s ± 20kc/s.Table 2. Absolute Maximum RatingsSPCM Ordering GuideExample: SPCM-AQRH-43 = 10ns output pulse width, 22ns dead time, 4.4V output pulse height, dark count < 250cpsTable 3B – Optical bracket/adaptor options:(1) See figure 9 and figure 10See Table 3A Below See Table 3A BelowSee Table 3B BelowTable 4. Fibre Ordering GuideFigure 1. Electrical ConnectionsFigure 2. Typical SPCM-AQRH PDE Scan at 650 nmFigure 3. Typical Photon Detection Efficiency (PDE) vs. WavelengthFigure 4. Photon detection probability (PD) uniformity vs. Light spot sizeFigure 6. Probability of Detection Variation vs. Module case TemperatureFigure 7. Count Rate LinearityFigure 8. Optical Power vs. Number of PhotonsFigure 9. Dimensional OutlineFigure 10. Optical Bracket / Adaptor OutlineSPCM-AQRH-WX-BR1: SPCM-AQRH-WX-BR2:with bracket for 1" tube (1.035” x 40TPI)with bracket for C-mount (1.0” x 32TPI)and 30mm cage mount and 30mm cage mountOptical Mount Bracket OptionsThere are two optical mounting bracket options available to the module. The mounting brackets are factory installed and cannot be removed by end users without risk of damaging the detector, thus voiding the warranty to the module.These mounting brackets are for industry standard C-mount and Cage Mount systems, such as those offered by Excelitas’ Qioptiq division: a tube system and a cage system called Microbench that can be attached to the mounting brackets. These systems provide a high flexibility in building customized setups tailored to any specific need. In addition, a vast portfolio of optical components that can be integrated into these systems is offered by Qioptiq. There is also an adapter that allows a combination of the metric Microbench system with other cage systems based on the SM1 standard or vice versa.SaturationThe photon count decreases at higher incoming light levels. The count at which the output rate starts to decrease is called the saturation point. As an extreme example, if the module is exposed to intense light the count rate will fall to zero. While the module is protected against light overload, precautions should be taken to avoid any excessive light level that will damage the SPCM module. After an over exposure, the dark count of the module could increase temporarily for up to an hour. For faster recovery, it is recommended to power off the module and leave it in the dark for one to two minutes prior to restarting. Fibre Connection OptionThe SPCM-AQRH-WX-FC has an “FC” fibre-optic receptacle pre-aligned to the optical detector. Optical fibres with an FC connector on one end are available separately, (see Ordering Guide 2). The standard fibre lens is optimized for 550nm. Though the fibre / GRIN in the standard module will function through the complete range of 400nm to 1060nm, due to the wavelength-dependence of the graded index coupling lens, improvements to operating wavelengths other than 550 nm are special orders. The photon detection efficiency of connectorized modules is about 95% of that quoted for standard modules at 550nm.Fibre ShieldingWhen used with optical fibres, both the fibre jacket and the connector shrouds must be completely opaque. Otherwise, stray light will increase the count rate. The SPCM-QCX pigtails conform to this requirement (see Ordering Guide in Table 4). Gating FunctionA gating function is provided with each module – useful for viewing a signal that occurs only in a small timeframe window. Also, in some applications the background light flux is higher than the signal. In this case, the gating option could be used to improve the S/N ratio by opening a window only when the light signal is present. The output of the module and the active quench function are disabled when a TTL low level is applied to the module gate input. When a TTL high level is applied to the module gate input, the output of the module and the active quench circuit are enabled again. Any photon detection that occurs less than 2μs before the module gate input changes can result in an output pulse. However, this output pulse has lost timing accuracy.Light Emission during Photon DetectionOne peculiarity of silicon avalanche photodiodes operating in Geiger mode is that as an incoming photon is detected a small amount of light is emitted from the avalanche region. The emitted light has a broad spectral distribution. In most cases, this is not a problem. However, it can cause some confusion if another detector is monitoring light, or if the optical system is such that light emitted from the SPCM-AQRH is reflected back on itself. If these photons return more than 20 ns after the initial event, they will be detected.Power SupplyThe SPCM is relatively insensitive to power supply noise. It can handle +/- 100mV of ripple without much difficulty. A low impedance path for the ground line to the module is desirable. Generally, any reasonable quality power supply are acceptable. The power supply must be able to support between 4.8 –5.25V, and up to 1.2A current. Whether it’s a linear or switch type of supply is not critical as long as the ripple and noise is kept below 50mV.Safety WarningThe SPCM-AQRH contains a high voltage power supply. Users may be injured if the case is opened. All internal settings are pre-set; there are no user adjustments.Units that appear defective or have suffered mechanical damage should not be used because of possible electrical shorting of the high voltage power supply. Opening the case may damage sensitive components and expose the user to the risk of electrical shock. Please contact factory for repairs.RoHS ComplianceThis series of avalanche photodiode modules are designed and built to be fully compliant with the European Union Directive 2015/863/EU – Restriction of the use of certain Hazardous Substances in Electrical and Electronic equipment.WarrantyA standard 12-month warranty following shipment applies. Any warranty is null and void if the module case has been opened. Warranty is null and void if the module input exceeds 5.5 V or the polarity of the +5 V supply is reversed.ESD WarningModules should only be handled at an ESD-safe work station.Individual Module Test DataEach module is supplied with test data indicating the module’s actual dark count, dead time, pulse width, photon detection efficiency @ 630nm (550nm for fiber-coupled versions), correction factor and linearity.Declaration of ConformityThis product is eligible to bear the ETL mark with adjacent indicator ‘C’ and ‘US’. The Intertekcontrol number is 4010815.Products:CLASS 8721 85 ELECTRICAL EQUIPMENT FOR LABORATORY USE – Certified to US standardsCLASS 8721 84 ELECTRICAL EQUIPMENT FOR LABORATORY USE – Certified to US standardsCLASS 8721 04 LABORATORY EQUIPMENT – ElectricalCLASS 8721 04 LABORATORY EQUIPMENT – ElectricalSingle photon counting module SPCM-AQRH or SPCM-AQRH-WX (where W = 1,2,3,54,5,6 and X = 0, 1, 2, 3, 4, 5, 6 are not affecting safety certification), rated 5Vdc, 1.2A.Single photon counting module SPCM-AQRH-WX-FC or SPCM-AQR-WX-FC model SPCM-AQRH-WX-FC or SPCM-AQR-WX-FC (where W = 1,2,3,4,5,6 and X = 0, 1,2, 3, 4, 5, 6 not affecting safety certification), rated 5Vdc, 1.2A.Single photon counting module SPCM-CDXXXXY (where X = can be 0000 to 9999, Y could be a letter from A to Z, not affecting safety certification), rated 5Vdc, 1.2A.Altitude of Operation: 0 – 5000 Meters.Humidity of Operation: 15% - 95% relative humidity, non-condensing Equipment class III, measurement category I, pollution degree 2.APPLICABLE REQUIREMENTS: CAN/CSA C22.2# 61010-1 Issue: 2012/05/11 Ed:3 SAFETY REQUIREMENTS FOR ELECTRICAL EQUIPMENT FOR MEASUREMENT, CONTROL, AND LABORATORY USE -PART 1: GENERAL REQUIREMENTS.UL 61010-1 Issued: 2012/05/11 Ed:3 SAFETY REQUIREMENTS FOR ELECTRICAL EQUIPMENT FOR MEASUREMENT, CONTROL, AND LABORATORY USE - PART 1: GENERAL REQUIREMENTS.This product is eligible to bear the CE mark in accordance with:EN 61326-1:2013 Electrical equipment for measurement, control and laboratory useEN 61010-1:2012 Safety requirements for electrical equipment for measurement, control and laboratory useThis product has been tested as per the following standards:∙Emission CISPR 11∙IEC 61000-4-2 ESD∙IEC 61000-4-3 Radiated susceptibility∙IEC 61000-4-4 Burst∙IEC 61000-4-5 Surge∙IEC 61000-4-6 Conducted susceptibility∙IEC 61000-4-11 Voltage dips and interruptionsThe object of the declaration described herein is in conformity with the relevant EU legislation: EMC Directive 2004/108/EC (through April 19, 2016) and EMC Directive 2014/30/EU (from April 20, 2016).This equipment is intended for Indoor Use Only. There is no applicable maintenance manual. The data sheet is used also as an instruction manual.Excelitas Technologies reserves the right to make changes, improvements, modifications and corrections to its products. Excelitas Technologies reserves the right to discontinue its products. Buyers should obtain the latest information about the product before placing orders.About Excelitas TechnologiesExcelitas Technologies is a global technology leader focused on delivering innovative, customized solutions to meet the detection, lighting, and other high-performance technology needs of OEM customers.From analytical instrumentation to clinical diagnostics, medical, industrial, safety and security, and aerospace and defense applications, Excelitas Technologies is committed to enabling our customers' success in their end-markets. 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盖革-米勒计数器科技名词定义中文名称：盖革-米勒计数器英文名称：Geiger-M黮ler counter;GM counter其他名称：盖革计数器盖革-米勒计数器一种专门探测电离辐射(α粒子、β粒子、γ射线)强度的记数仪器。

由充气的管或小室作探头，当向探头施加的电压达到一定范围时，射线在管内每电离产生一对离子，就能放大产生一个相同大小的电脉冲并被相连的电子装置所记录，由此测量得单位时间内的射线数。

英文Geiger-Müller counter介绍气体电离探测器。

是H.盖革和P.米勒在1928年发明的。

与正比计数器类似，但所加的电压更高。

带电粒子射入气体，在离子增殖过程中，受激原子退激，发射紫外光子，这些光子射到阴极上产生光电子，光电子向阳极漂移，又引起离子增殖，于是在管中形成自激放电。

为了使之能够计数，计数器中充有有机气体或卤素蒸气，能吸收光子，起到猝熄作用。

盖革-米勒计数器优点是灵敏度高，脉冲幅度大，缺点是不能快速计数。

1908年，德国物理学家盖革（Hans Wilhelm Geiger,1882-1945）（左图）按照卢瑟福（E. Ernest Rutherford，1871～1937）的要求，设计制成了一台α粒子计数器。

卢瑟福和盖革利用这一计数器对α粒子进行了探测。

1909年盖革和马斯登（Ernest Marsden，1889-1970）在实验中发现α粒子碰在金箔上偶尔会发生极大角度的偏折。

卢瑟福对这个实验的各种参数作了详细分析，于1911年提出了原子的有核模型。

从1920年起，盖革和德国物理学家米勒（E. Walther Muller，1905-1979）对计数器作了许多改进，灵敏度得到很大提高，被称为盖革-米勒计数器，应用十分广泛。

盖革-米勒计数器是根据射线能使气体电离的性能制成的，是最常用的一种金属丝计数器。

两端用绝缘物质封闭的金属管内贮有低压气体，沿管的轴线装了金属丝，在金属丝和管壁之间用电池组产生一定的电压（比管内气体的击穿电压稍低），管内没有射线穿过时，气体不放电。

光子计数的方法
光子计数方法是一种测量光子数量的技术，其原理基于光子的粒子性质。

以下是常见的光子计数方法：
1. 单光子探测器：单光子探测器是一种能够在光子到达时精确地检测到单个光子的器件。

常见的单光子探测器包括光电倍增管（PMT）、单光子级联器件（SPAD）和超导单光子探测器（SSPD）等。

通过记录单光子探测器发出的脉冲数量，可以计数光子的个数。

2. 相干态测量：相干态测量方法利用光子的干涉和相干性质来计数光子的数量。

常见的方法包括干涉实验和光学混频器。

干涉实验使用干涉仪将待测光与已知强度的参考光进行干涉，通过干涉图案的变化来确定光子的数量。

光学混频器利用两束相干光的相位差，使它们在混频器中混合，通过混合后的光的幅度变化来计数光子的个数。

3. 统计方法：统计方法是通过光子的概率分布来计数光子的个数。

常见的统计方法包括计数率测量、时间相关单光子技术（TCSPC）和光子统计成像等。

计数率测量是通过持续时间内光子脉冲的计数来估计单位时间内的光子个数。

TCSPC技术通过测量不同光子脉冲之间的时间间隔来计数光子的个数。

光子统计成像则是通过在空间上扫描并记录每个位置接收到的光子数量来获得光子分布图像。

这些方法在不同的应用领域具有广泛的应用，包括量子通信、光子计算、量子态的制备与操控、生物医学成像等。