激光粉尘PM2.5传感器

pm2.5激光传感器原理解读pn学堂
PM2.5激光传感器可以通过测量空气中悬浮颗粒物（PM2.5）的浓度来评估空气质量。

它的工作原理如下：
1. 激光发射器：首先，激光传感器会通过一个激光发射器产生一束激光束。

2. 高效散射器：激光束会射向一个高效散射器（也称为散射体），该散射器能够让激光束与空气中的颗粒物发生散射。

3. 接收器：在散射过程中，散射的光线会进入传感器内部的一个接收器，接收器将接收到的光信号转换为电信号进行处理。

4. 光散射信号分析：接收到的光信号会经过分析，通过测量光的散射角度和强度来判断空气中的颗粒物浓度。

5. PM2.5浓度计算：通过根据散射的角度和强度来估计颗粒物的大小，进而计算出PM2.5浓度。

总的来说，PM2.5激光传感器利用激光的散射特性来测量空气中颗粒物的浓度，进而评估空气质量。

该传感器具有高精度、快速响应和可靠性等优点，在环境监测和空气净化设备中得到广泛应用。

济南诺方电子技术有限公司SDS018传感器激光PM2.5传感器规格书产品型号：SDS018版本：V1.6概述SDS018激光PM2.5传感器又称粉尘传感器，使用激光散射原理，能够得到空气中0.3～10微米悬浮颗粒物浓度，使用进口激光器与感光部件，数据稳定可靠；内置风扇，数字化输出，集成度高。

采用优化光路、风道设计及自校准参数算法，PM2.5一致性好。

尺寸、安装方式及信号接口兼容大多数红外粉尘传感器，是理想的升级产品。

特点●数据准确：激光检测，稳定、一致性好；●响应快速：数据更新频率为1Hz ；●便于集成：串口输出（或IO 口输出可定制），自带风扇；●分辨率高：分辨颗粒最小直径达0.3微米；●一致性好：优化光路、风道设计及自校准参数算法，PM2.5一致性好；●兼容红外：尺寸、安装方式及信号接口可兼容红外粉尘传感器，无需更改模具及控制板即可实现快捷升级；●标准认证：产品已通过CE/FCC/RoHS认证。

适用范围PM2.5检测仪、净化器、新风系统及其他空净检测领域。

工作原理激光粉尘传感器采用激光散射原理：当激光照射到通过检测位置的颗粒物时会产生微弱的光散射，在特定方向上的光散射波形与颗粒直径有关，通过不同粒径的波形分类统计及换算公式得到不同粒径的实时颗粒物的数量浓度，按照标定方法得到跟官方单位统一的质量浓度。

技术指标3456额定电压额定电流休眠电流温度范围5V 60mA±10mA<4mA存储环境：-20~+60℃工作环境：-10~+50℃存储环境：最大90%工作环境：最大70%86KPa~110KPa1s 1Hz 0.3μm±15%和±10μg/m3的最大值59x45x20mm CE/FCC/RoHS25℃，50%RH激光器，风扇停止工作7891011121314湿度范围工作大气压力响应时间串口数据输出频率最小分辨粒径相对误差产品尺寸标准认证电源要求电源电压：4.7~5.3V电源功率：大于1W （电流大于200mA ）电源电压纹波小于20mV使用寿命使用寿命是激光粉尘传感器的关键指标之一，诺方激光粉尘传感器使用高质量长寿命的进口激光二极管，使用寿命长达8000小时，对于连续使用时间不长的应用场合（例如检测仪）可使用默认配置1Hz 连续测量，对于需要连续使用的应用场合（例如净化器，空气质量监控等），可以使用间歇开机测量的方式延长使用寿命，例如1分钟开机20秒，关机40秒可将使用寿命延长至3倍。

激光pm2.5传感器是什么
细颗粒物又称细粒、细颗粒、PM2.5。

细颗粒物指环境空气中空气动力学当量直径小于等于2.5
微米的颗粒物。

它能较长时间悬浮于空气中，其在空气中含量浓度越高，就代表空气污染越严重。

虽然PM2.5只是地球大气成分中含量很少的组分，但它对空气质量和能见度等有重要的影响。

与较粗的大气颗粒物相比，PM2.5粒径小，面积大，活性强，易附带有毒、有害物质，对人的危害非常大，随即出现了激光pm2.5传感器的名词，那激光pm2.5传感器是什么呢?
激光PM2.5传感器又称作为粉尘传感器，SDS021使用激光散射原理，能够得到空气中0.3～10微米悬浮颗粒物的PM2.5和PM10浓度。

使用进口激光器与感光部件，体积小，数据稳定可靠;内置风扇，数字化输出，集成度高。

特点：
数据准确：激光检测，稳定、一致性好;l
响应快速：数据更新频率为1Hz; l
便于集成：串口输出，自带风扇;
分辨率高：分辨颗粒最小直径达0.3微米;l
内切割器：内部专业螺旋风道，有效物理切割小颗粒，使测量更准确;
防絮设计：专门计算栅栏间距进风口，有效阻挡柳絮等絮状物;
清洁孔：独立的清洁孔设计，方便维护;
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污染安全小知识，希望对您有所帮助。

品名：PM2.5激光传感器型号：LD15（A版）广州勒夫迈智能科技有限公司研发中心目录一、产品概述 (3)二、工作原理 (3)三、主要特性 (4)四、接口定义 (6)五、应用电路 (7)六、输出结果 (7)八、产品安装尺寸图 (12)安装注意事项 (13)附录一：通讯协议 (14)协议A（默认）： (14)协议B： (16)一、产品概述LD15是一款基于激光米氏MIE散射理论的高精度颗粒物浓度传感器，可连续采集并计算单位体积内空气中不同粒径的悬浮颗粒物个数，即颗粒物浓度分布，进而换算成为质量浓度，并以通用数字接口形式输出。

本传感器可嵌入各种与空气中悬浮颗粒物浓度相关的仪器仪表或环境改善设备，提供及时准确的浓度数据。

.二、工作原理LD15激光传感器采用米氏Mie球形颗粒散射原理,即激光传感器使用激光照射在空气中的悬浮颗粒物上产生光散射，光电探测器在某一角度范围内收集散射光强，将得到散射光强线性地转换成电压，然后送入数据处理系统，数据处理系统按事先编制的程序根据米氏散射理论进行数据处理，得出颗粒物的等效粒径及单位体积内不同粒径的颗粒物数量。

三、主要特性◆ 激光米氏MIE球形散射原理结合勒夫迈空间测量专利实现精准测量◆ 零错误报警率◆ 实时响应并支持连续采集◆ 最小分辨粒径0.1μm◆ 电控器件寿命≥8年，平均工作无故障时间≥5年◆ 六面全方位屏蔽结合软件抗干扰算法，抗干扰性能更强◆ 适用范围广，无需再进行风道设计，兼容多协议输出。

◆ 设计轻薄，适用于检测仪、穿戴设备、空气净化器、新风系统等。

表1传感器技术指标1000u g/m3以上以实测为准。

注2：颗粒物浓度一致性数据为通讯协议中的数据（见附录一）测量环境条件为20℃，湿度50%传感器功能部分框图如下所示：四、接口定义..PIN1PIN8五、应用电路六、输出结果主要输出为单位体积内各浓度颗粒物质量以及个数，其中颗粒物个数的单位体积为0.1升，质量浓度单位为：微克/立方米。

PM2.5传感器
1 概述
PM2.5传感器是利用激光散射原理，对空气中存在的粉尘颗粒物进行探测，最小可以检测到1.0微米的颗粒，具有良好的一致性和稳定性。

2 特点
（1）高灵敏度、高分辨率。

（2）低功耗、响应时间快。

（3）卓越的线性输出。

（4）优异的稳定性。

（5）使用寿命长。

3 适用范围
广泛应用于空气质量监测、新风系统、智能家居、学校、医院、办事大厅、火车站等需要检测空气质量的领域及场所。

4 产品资料
4.1 技术参数
测量参数：PM2.5浓度
单位：μg/m3
检测范围：0～1000μg/m3
分辨率：1μg/m3
精度：±10%F·S（25℃）
输出信号：A：电压信号（0～2V，0～5V，0～10V三者选一）B：4～20mA（电流环）
C：RS485（标准Modbus-RTU协议，设备默认地址：01）
供电电压：7～24V DC（当输出信号为0～2V，RS485时）
12～24V DC（当输出信号为0～5V，0～10V，4～20mA时）工作温度：－30℃～50℃
储存温度：－40℃～60℃
工作湿度：15～80%RH（无凝结）
温度漂移：0.2%F·S/℃
平均电流：50mA@7V；35mA@12V；20mA@24V 稳定性：≤2%F·S
重复性：≤1%F·S
预热时间：3min
响应时间：＜90s。

DSENSOR数字式通用颗粒物浓度传感器PMSX0XX系列数据手册V1.2主要特性u零错误报警率u实时响应u数据准确u最小分辨粒径0.3微米概述PMSX0XX系列是一款数字式通用颗粒物浓度传感器，可以用于获得单位体积内空气中悬浮颗粒物个数及质量，即颗粒物浓度，并以数字接口形式输出。

本传感器可嵌入各种与空气中悬浮颗粒物浓度相关的仪器仪表或环境改善设备，为其提供及时准确的浓度数据。

工作原理本传感器采用激光散射原理。

即令激光照射在空气中的悬浮颗粒物上产生散射，同时在某一特定角度收集散射光，得到散射光强随时间变化的曲线。

进而微处理器利用基于米氏（MIE）理论的算法，得出颗粒物的等效粒径及单位体积内不同粒径的颗粒物数量。

传感器各功能部分框图如图1所示图1 传感器功能框图技术指标如表1所示表1 传感器技术指标参数指标单位测量范围0.3~1.0；1.0~2.5；2.5~10 微米（μm）计数效率50%@0.3um 98%@>=0.5 um称准体积0.1 升（L）响应时间≤10 秒（s）直流供电电压 5.0 伏特（V）最大工作电流120 毫安（mA）待机电流≤200 微安（μA）数据接口电平L <0.8 @3.3 H >2.7@3.3 伏特（V）工作温度范围-20~+50 摄氏度（℃）工作湿度范围0~99%平均无故障时间≥3 年（Y）最大尺寸65×42×23毫米（mm）输出结果主要输出为单位体积内各浓度颗粒物质量以及个数（视具体型号）数字接口1.接口描述数据接口：其中2针为串行数据通信接口，采用通用异步收发协议（UART）；1针为控制信号接口，采用高低电平控制，所有电平均为3.3VTTL电平。

2.接口管脚定义说明图2 数字接口管脚定义PIN1 VCC 电源正5VPIN2 GND 电源负PIN3 SET 设置管脚/TTL电平@3.3VPIN4 RXD 串口接收管脚/TTL电平@3.3VPIN5 TXD 串口发送管脚/TTL电平@3.3VPIN6 RESET 模块复位信号/TTL电平@3.3VPIN7\8NC 悬空注：SET=1模块工作在连续采样方式下，模块在每一次采样结束后主动上传采样数据，采样响应时间小于600毫秒，数据更新时间小于2秒。

激光PM2.5传感器规则书CP-15-A3激光pm2.5传感器CP-15-A3第三代激光粉尘颗粒物浓度传感器规格书■产品描述CP-15-A3是一款激光数字式通用颗粒物浓度传感器。

内含激光器和光电接收管组件，采用光散射原理，通过激光在粉尘颗粒物上发生散射并由光电变换器变为电信号，从而进行复杂的算法检测到空气中不同粒径的颗粒物数量，进而得到颗粒物浓度。

稳定可靠的激光检测技术与精良的电路设计紧密相结合，使得本传感器更加出众。

■特性1.紧凑外形（57 x 43 x 23 mm），质量轻(45g)2.数据精准3.独有双频数据采集功能4.独有激光防衰减技术5. 50个标定锚点进行标定6.响应迅速(≦10秒)7. 能够区分室内香烟等小颗粒和粉尘（花粉，尘埃，毛屑）等大颗粒8. 最小分辨粒径0.3微米9. 具备抗干扰能力10. 标准串口输出11.符合ROHS（2011/65/EU）规定■应用场景1. 空气中的粉尘检测，室内空气质量检测2.空气过滤器，空气净化机，新风空调等配套检测设备■内部原理图■外形尺寸单位mm■输出引脚定义输出接口为一个8针座，如图所示接口编号符号I/O或连接到描述1 VCC 电源电源输入端（+5V 端）2 GND 电源电源地3 SET I 对传感器设置(3.3V电平)4 RXD I 串口接收管脚(3.3V电平)5 TXD O 串口发送管脚(3.3V电平)6 RESET I 模块复位信号(低电平复位)7 - - 保留8 - - 保留注意：只需连接PIN1、PIN2、PIN5，其他PIN 脚无须连接。

■绝对最大值(Ta=25°C)绝对最大值参数符号最小最大单位工作温度Topr -10 50 ℃储存温度Tst -20 60 ℃工作湿度RH 5% 80% RH储存湿度RH 5% 95% RH■电气特性直流特性参数符号最小典型最大单位供电电压VCC 4.95 5.0 5.05 VI/O电压提供IOVCC 3.0 3.3 3.3 V工作电流I - - 120 mA■传感器技术指标参数指标单位测量范围0.3～10 微米（um）量程0～6000 ug/m3响应时间≤10 秒平均无故障时间-注①≥5 年精度（准确率）-注②98%注①：在正常的大气室内环境下，平均每天8小时正常工作，恶劣环境除外。

激光粒子传感器BL25B11.特征●传感器类型：90°光散射●分辨率：1µg/m³●测量范围：0to500µg●粒径尺寸：0.3to2.5µm●精度：±5µg（0to50µg）±15%（50to500µg）●校准源：TSI8530●噪声：11to16dB(A)●工作温度：0to50°C●存储温度：-20to60°C●操作湿度：0to95%RH,非凝结●检测时间常数：20-60秒●输入电压：DC_5.0V±100mV●通信方式：串口通信（外置TCXO，通信更稳定）●平均失效前时间(MTTF)：20000小时●尺寸：51.6×31.6×23.3mm●质量：30g●颜色：黑色●材质：ABS+PC2.应用●空气质量检测仪●室内空气质量检测●手持式颗粒物检测仪●空气清新机●空气净化器●其他3.说明BL25B1是一款用于检测空气悬浮颗粒质量浓度的传感器，它基于90°激光散射原理来测量悬浮颗粒物，激光粒子传感器均经过出厂校准。

结构设计包含大颗粒撞击壁，灰尘收集槽，这样可使传感器免受灰尘、粉尘以及其它大颗粒污染物的影响，从而提高耐用性。

长宽以及边沿倒角符合黄金比例，同侧进、出风设计方便应用安装的同时提供稳定的气流。

检测原理：风扇提供稳定的气流，当粒子流过激光的时候会产生光散射现象，结构上安装在90°方向的硅光电池会检测到散射的光线，通过光电二极管将光信号转变成电信号，经过电荷放大电路，以及模拟信号调理电路，进入MCU的ADC采集，通过数字信号处理算法，分析出电信号的脉冲高度以及单位时间的脉冲个数，脉冲数代表粒子数，脉冲高度代表粒子大小，最后和标准仪器（TSI8530）在密闭的空间进行出厂校准。

4.引脚说明外壳阴刻名称I/O说明V VCC-电源正极，直流5.0V,电源纹波小于100mVG GND-电源地R UART_RX I串口数据接收,兼容3.3V/5.0VT UART_TX O串口数据发送,兼容3.3V/5.0V附件1：1.25mm间距连接线4Pin端子线类型：双头同向线长：150MM数量：1根附件2：半圆头内六角螺钉型号：M2*10数量：3粒备注：波特率：9600；数据位：8；校验：None；停止位：1.0；控制流：无5.数据格式1．传感器数据输出数据方向：（传感器—>设备）Blue Loong长度数据高位数据低位时间常数校验0x420x4c0x05xx xx xx xx说明：该指令为传感器正常工作时以1S周期输出。

浅谈PM2.5传感器TF-LP01的应用原理与使用方法TF-LP01是日本figaro开发的民用级激光型PM2.5传感器，是利用光散射原理对空气中粉尘颗粒进行检测的小型模组，能精准检测到具体PM1.0、PM2.5、PM10的数值，USART（3.3V TTL电平）和PWM（需定制）输出，具备体积小、检测精度高、重复性好、一致性好、实时响应可连续采集、抗干扰能力强、采用超静音风扇，传感器出厂100%检测和标定等优点，适用于各种需要进行PM值检测的场合。

目前，TF-LP01已广泛在以下领域得到很好的应用：1.适用于工矿企业劳动部门生产现场粉尘浓度的测定-煤矿粉尘检测2.卫生防疫站公共场所可吸入颗粒物的监测3.环境环保监测部门大气飘尘检测，污染源调查4.市政监烟5.科学研究，滤料性能试验等方面现场测试6.现场粉尘浓度测定，排气口粉尘浓度监测7.药品制造测试8.职业健康和安全检测9.工厂需要清洁空气的地方，精密仪器，测试仪器，电子部件，食品，药品等制造工艺的管理10.各种研究机构，气象学，公众卫生学，工业劳动卫生工程学，大气污染研究等11.建筑或爆破的地方的粉尘检测，工地场所暴露监测12.室内空气质量检测，空气净化，例如：空气净化器、空调、抽湿机、新风机或系统，甲醛检测仪、智能家居等13.车载行业，车内空气检测和净化，移动车载城市空气检测站TF-LP01一方面可以直接通过串口调试助手在电脑上检测数据，一方面可以通过MCU 开发在产品应用，使用方法简单介绍如下：TF-LP01如何在电脑端进行调试测试，查看数据呢？简单介绍如下：一、工具准备TF-LP01传感器（包含连接线）、电脑、串口调试助手、pl2303（USB转串口驱动)、USB 转 TTL 串口线二、操作使用1.先在电脑端安装串口调试助手和pl2303驱动；B 转 TTL 串口线，接上 PM2.5 传感器，插上电脑，传感器引脚定义以及连线方式如下：传感器1脚为VCC-接转串口中的电源正极传感器2脚为GND-接转串口中的电源负极传感器4脚为RXD-接转串口中的TXD传感器5脚为TXD-接转串口中的RXD2.通电后，在电脑打开串口调试助手软件，进行串口配置和通讯参数设置（1）串口号配置打开电脑设备管理器，了解串口号信息（2）通讯参数配置，主要设置波特率、校验位、数据位、停止位，（参考例子）3.点击连接，打开串口，串口调试助手会自动收到传感器上传的收据，单次上传17个字节的16进制数据代码。

/
FM-PN PM2.5传感器
FM-PN PM2.5传感器产品描述：
PM2.5激光传感器是一款通用细微颗粒物浓度传感器，用于获得空气中单位体积内PM2.5 和PM10
的质量数据。

本传感器可嵌
入各种细微颗粒物浓度相
关的仪器仪表、环境改善设
备中，或用于其他需要检测
PM2.5 浓度的场合。

FM-PN PM2.5传感器产
品特点：
•实时给出PM2.5 及PM10的具体数值。

•测量准确
•响应迅速
•体积小
检测原理：
/ 本传感器采用激光散射原理。

即令激光照射在空气中的悬浮颗粒物上产生散射，同时在某一特定角度用探测器接收散射光，产生的光电流经放大后，得到电信号与颗粒物的对应曲线。

微处理器采集数据后，经过一系列算法得出单位体积内不同粒径的颗粒物质量。

FM-PN PM2.5传感器产品参数：
量程：1~1000ug/m3
分辨率：1ug/m3
最小分辨粒径：0.3um
测量精度(误差)：≤±10%
重复性(一致性)：≥±90%
响应时间：≤10s
采样流量：0.1升/分钟
工作温度：-10~60℃
工作湿度：0~90%RH
寿命：>30000小时
/ 工作电压：12-24V
信号输出：4-20mA或RS485
FM-PN PM2.5传感器应用领域：
室内外空气质量监测，空气过滤器,空气净化器，空调以及家用(车载、手持)空气检测仪。

Alphasense Ltd Page 1 of 15 September 2014The purpose of this manual is to explain how to set up, install and use the Alphasense Optical Particle Counter OPC-N1 for measuring PM1, PM2.5 and PM10, as well as measuring the particle size distribution in real time.1 OPC-N1 Provisional SpecificationTable 1 below specifies power and environmental performance and limits.MEASUREMENTParticle range (um)Spherical equivalent size 0.38 to 17Size categorisation (standard)Number of software bins 16Sampling interval (seconds)Histogram period 1 to 10Flow rateL/ min 1Particle count rateParticles/ second 10,000Coincidence probability% concentration at 106 particles/L 0.24POWERMeasurement mode (mA)Continuous measurement 260Laser power (mW)Typical, at 658 nm 5-8Standby mode (mA)Fan off 186KEY SPECIFICATIONSDigital InterfaceSPI (Mode 1)Laser classification3B Temperature range°C -10 to 50Humidity range% rh (continuous)0 to 99 (non-condensing)Weight g < 70Table 1. Specifications for OPC-N12How it WorksLike conventional optical particle counters, the OPC-N1 measures the light scattered by individual particles carried in a sample air stream through a laser beam. These measurements can then be used to estimate particle size (proportional to the amount of light scattered) and particle number concentration. Estimates of particle mass loading, eg: PM 2.5 or PM 10, can then be determined from the particle size spectra and concentration data.Most conventional OPCs must employ narrow inlet tubes (and often an additional ‘sheath-flow’ of particle-free air) to physically constrain the airborne particles to the more uniform central part of the laser beam and ensure accurate sizing. Such instruments must therefore incorporate both an air-pump sufficiently powerful to draw the sample aerosol through the narrow inlet tube and a particle filter upstream of the pump to avoid pump contamination and ultimate blockage. The result is a unit with relatively high current consumption and a periodic requirement (frequent in dirty atmospheres) to replace the pump protection filter.However, the OPC-N1 uses a fundamentally different approach that removes the need for both the pump and a replaceable particle filter. Instead, it uses a combination of custom-designed elliptical mirror and a dual-element photodetector to create a ‘virtual sensing zone’ in free space at the centre of an open scattering chamber. The sensing zone and its surrounding space is then illuminated by a thin ribbon-shaped laser beam. Particle-laden air passing unconstrained though the scattering chamber can traverse the laser beam both within and outside the sensing zone, but only those particles traversing within the sensing zone are ‘validated’ by the dual-element detector and counted/sized by the OPC electronics.The result is a new sensor that can use a miniature low-power fan instead of a pump to generate the required particle flow through the sensing volume and does not require any form of particle filter. This obviates the need for periodic manual intervention to replace the conventional pump protection filter and instead allows long periods of unattended field operation.In the OPC-N1, each particle, at rates up to ~10,000 particle per second, is classified as to its particle size and added to one of 16 “bins” covering the size range from 0.38 to 17 μm. The resulting particle size histograms can be evaluated over user-defined sampling times from typically 1 to 10 second duration, the histogram data being transmitted along with other diagnostic and environmental data (chamber temperature and air pressure) via an SPI interface to a host computer.Notes1 The patented OPC-N1 design results in virtually all sampled airborne particles passingstraight through the sensor without being deposited. This allows the OPC-N1 to operate for potentially very long (>1 year) periods without the requirement for regular maintenance or cleaning. If you are concerned about particulate/ contaminate build-up and loss of performance, then contact Alphasense.2 Particle coincidences (two particles within the sensing zone at the same time) may occur,though software algorithms partially correct for such effects. The probability of particle coincidence is approximately 0.24% for particle concentrations of 1000 per ml.3 As with most commercial Optical Particle Counters, all particles, regardless of shape, areassumed to be spherical and are therefore assigned a ‘spherical equivalent size’. This size is related to the measurement of light scattered by the particle by so-called Mie theory, an exact theory to predict scattering by spheres of known size and refractive index. The OPC-N1 is calibrated using Polystyrene Latex Spherical Particles of a known diameter and known refractive index. Correction factors may be applied in future versions of the PC software to reduce errors resulting from airborne particles of different refractive index. Alphasense Ltd Page 2 of 15 September 20143PM measurementsThe particle size histogram data recorded by the OPC-N1 sensor can be used to estimate the mass of airborne particles per unit volume of air, normally expressed in μg/m3.There are accepted International Standards Organisation (ISO) definitions of particle mass loadings in the air, for example: PM1, PM2.5 and PM10. These relate to the mass and size of particles that would be inhaled by a typical adult. So, for example, PM2.5 is defined as ‘particles which pass through a size-selective inlet with a 50% efficiency cut-off at 2.5 μm aerodynamic diameter’. The 50% cut-off indicates that a proportion of particles of larger than 2.5 μm will be included in PM2.5, the proportion decreasing with increasing particle size out to approximately 10μm particles.The current version of OPC-N1 software does not calculate the ISO definition of the PM masses (although later versions will do this). Instead, the OPC-N1 calculates and plots a set of continually updated time-series graphs which show:- <=PM1 – ie: the mass (in μg/m3) of all particles below 1 μm in size.- <=PM2.5 – ie: the mass (in μg/m3) of all particles below 2.5 μm in size.- <=PM10 – ie: the mass (in μg/m3) of all particles below 10 μm in size.The conversion from the ‘optical size’ of each particle recorded by the OPC-N1 and the mass of that particle requires a knowledge of both the density of the particle material and its refractive index at the wavelength of the illuminating laser beam (658 nm). Since in most field measurement situations this information is not known accurately (and indeed there may be a variety of particles present with different densities and refractive indices), it is usual to apply a ‘correction factor’ to the particle mass as recorded by the OPC. This OPC-N1 software has a default setting for the correction factor which may be altered by the user if required to allow the measured mass to be aligned as closely as possible with the particle mass concentration in the air as measured by a direct method (eg: weighing particles collected on a filter).Note: The OPC-N1 calculations of particle mass assume a negligible contribution from particles below 0.38 μm, the lower limit of particle detection of the OPC-N1 sensor.4 Health and SafetyThe OPC-N1 uses a diode laser light source. This diode laser operates at typically 5-8 mW at a wavelength of 658 nm. This laser is classed as a 3B type laser; 3B rating includes laser light up to 500 mW power. This product is designed for OEM use and will normally be mounted in a secondary housing. We do not recommend that the user open or adjust any parts of the OPC-N1. It is the user’s responsibility to ensure that the unit is used safely.DO NOT remove the black cover: this protective cover not only ensures the required airflow but also protects the user from the laser light.Some of the components are static sensitive, so only touch the circuit when properly grounded and use correct procedures for handling electrostatically sensitive devices.There are no user-adjustable components.DO NOT adjust the laser power potentiometer: this will alter the calibration and may increase the laser power above typical 5-8mW.Alphasense Ltd Page 3 of 15 September 20145 Connecting power and taking readingsThe OPC-N1 is shipped pre-calibrated, with no user adjustments. Power and communications areprovided via the SPI socket.Connection can be either via the SPI/ USB connector (Alphasense part number 000-0SPI-00)direct to a PC or to your own circuit’s internal bus using your own-provided SPI interface.that you use the SPI/ USB cable. You canthen view the data options and data resolutionand range when the OPC-N1 is connected toyour PC, when the Alphasense-suppliedsoftware is installed (Apple compatiblesoftware is not yet available).The SPI/ USBconnection cable is shown in figure 1 below.The green LED shows that power is suppliedto the OPC-N1, and the red LED flashes whenthe PC and OPC-N1 are communicatingFigure 1. SPI/ USB cable. USB socket connects to USB port on PCs via USB/ USB cable.SPI ConnectionWhen connecting direct to your own SPI connector, the SPI pinouts are:Pin Function1Vcc2SCK3SDO4SDI5/SS6GNDPin 1 is closest to the mounting pillar and R29.6 Sampling the environmentAlthough the OPC-N1 controls the fan speed to ensure correct flow rate, do not include anytubing, valves, baffles or obstructions that will restrict air flow- the entire OPC is designed for lowpressure drops. The OPC-N1 works best when the inlet is exposed direct to the sampling volumeand the fan is blowing the exhaust into a large space.Alphasense Ltd Page 4 of 15 September 2014Alphasense Ltd Page 5 of 15 September 20147 Software installationThe examples below are for installation using Microsoft Windows XP and Microsoft Windows 7 It is recommended that the Windows PC is running .NET version 4.0 or above.Installing the device driver (Windows XP)Copy the folder “CD Version OPC Interface V7” to the PC desktop. Connect the USB interface lead to the PC. If the USB interface lead (USB to SPI converter) is connected to the PC for the first time, Windows will need a device driver and this will start the “Found new hardware wizard”Select the “Yes, this time only” option and click next.The following window will give you an option as to whether to use a CD to install the device driver or to use another location. Select “Install from a list or a specific location (Advanced)”.Navigate to the OPC folder containing the folder named “USB Driver”, this contains the driver file devtech2.infwhich Windows needs to drive the OPC device.Alphasense Ltd Page 6 of 15 September 2014Click OK to allow Windows to locate and install the device driver. This process is automatic but you will be prompted by the form below to confirm the installation.Click “Continue Anyway” to finish the installation.Once the device driver is installed correctly the OPC device should appear in the Device Manager window as a “Communication Port” with an assigned COM port number. Make a note of this assigned port number, as you will need it when starting the software.The Driver installation is now complete.Alphasense Ltd Page 7 of 15 September 2014Installing the device driver (Windows 7)Copy the folder “CD Version OPC Interface V7” to the PC desktop. Connect the USB interface lead to the PC. If the USB interface lead (USB to SPI converter) is connected to the PC for the first time Windows will need a device driver.Open the system properties and locate the device manager.Windows 7 will show the new device as “USB-ISS” with a yellow exclamation mark indicating adriver problem.Alphasense Ltd Page 8 of 15 September 2014Right click the icon and select “Update Driver Software…Select the “Browse my computer for driver software” option.Navigate to the folder “CD Version OPC Interface V7” copied to your desktop and locate the folder named “USB Driver”, Click Next.Windows 7 will then issue a security warning. This is due to a licence issue and not a concern tothe operating system. Select the “Install this driver software anyway” option.Alphasense Ltd Page 9 of 15 September 2014Windows will then install the driver files for the device.Once the device driver software has been installed the form below will be displayed. Make a noteof the allocated COM port number (COM4 in the example below)Alphasense Ltd Page 10 of 15 September 2014Incorrect installation of the device driverIf the device driver is installed incorrectly the Device Manager will indicate this with a yellow exclamation mark symbol shown below.If this should happen remove the USB lead and uninstall the device by right clicking the symbol and selecting “Uninstall”. Return to the beginning of the “Installing the device driver” (Windows XP or Windows 7) section.single folder (to be kept intact) and will run as a normal Windows application. The entire folder canbe deleted when redundant.Alphasense Ltd Page 11 of 15 September 2014Alphasense Ltd Page 12 of 15 September 2014Connecting the device and running the softwareConnect the USB interface lead and OPC device to the PC, If you are promoted for device drivers refer to the previous section of the User Manual. Double click the COPCv7.exe icon to start the software application.When the application is first started the main form will be in “start-up mode” as shown below.Select the allocated COM port to begin.1. This shows a list of COM ports available on the PC, be sure to select the correct port number. The software will not respond unless a port with an OPC device attached is selected.2.This shows that the software application is waiting for a device to be attached.12Alphasense Ltd Page 13 of 15 September 2014Setting up and using the software• Set particle density (Default 1.65 g/ml): Adjust this to suit the environment of the device.•Device information (Right hand side text window): This shows the current information relating to the attached device.• Start sampling: Starts the data output with the fan and laser running continuously• Start sequence: Starts the data output with the fan and laser running cyclically• Repeat interval ms: This sets the interval at which the data is read from the device in milliseconds.• Y max: This sets the maximum count size of the histogram bins (Histogram functions only)•Histogram #/s: This shows the particle count per particle size.Alphasense Ltd Page 14 of 15 September 2014• Histogram #/ml: This shows the particle count per millilitre of sample.•History plot #/s: This shows the particle count per particle size Vs the time passed.Alphasense Ltd Page 15 of 15 September 2014• History plot mass conc: This shows the particle count of all three bins Vs the time passed.Log fileThe application will also create a log file from all of the output bins into a single .CSV file. Once either of the “start” buttons is selected you will be asked if you require a log file. If you select “yes” to this you will be prompted for a file name and location to store the file. An example of the log file is included in the deployment package.Firmware versionsThere are two versions of the firmware currently available for the OPC-N1 device and each firmware version requires a different version of the SPI command list. The information window on the right of the main form shows the firmware version installed as the software first loads.1. V07e – This version of the firmware does NOT perform the calculation for PM1, PM2.5 and PM10values. Instead the software application calculates these values at run-time and displays the values as text (e.g “PM1 = 0.14 ug/m³”)2. V009 – This version of the firmware calculates the PM1, PM2.5 and PM10 values in addition to the values calculated by the software application. The firmware values for PM1, PM2.5 PM10 are displayed with an “i” suffix (e.g “PM1i = 0.14 ug/m³”). The PM values can be called via SPI command in version 009 of the firmware.3. V009a – This version of the firmware is identical to V009 but the SPI chip select signal is utilised.*The orginal version of the OPC interface will NOT support V009 of the firmware. Please use the new version of the application as this will support both V07e and V009 firmware versions.Shutting down the softwareIt is recommended that the software application be closed before removing the USB interface lead so as to avoid USB communication errors.End of User Manual。