WXT520便携自动气象站

操作手册Vaisala 气象变送器WXT520M210906ZH-C出版人Vaisala Oyj 电话（国际长途）：+358 9 8949 1P.O.Box 26 传真：+358 9 8949 2227FIN-00421 HelsinkiFinland欢迎访问我公司网站：/© Vaisala 2013未经版权所有人事先书面许可，不得以任何形式或手段，无论是电子的还是机械的（其中包括影印），对本手册的任何部分进行复制，也不得将本手册的内容传达给第三方。

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________________________________________________________________________________目录第 1 章概述 (9)关于本手册 (9)本手册内容 (9)常规安全注意事项 (10)反馈 (10)ESD 保护 (11)产品回收 (11)商标 (11)许可协议 (12)法规遵从情况 (12)担保 (13)第 2 章产品简介 (15)气象变送器 WXT520 (15)加热功能 (16)简化设置的可选软件 (16)WXT520 变送器部件 (17)第 3 章功能介绍 (23)风测量原理 (23)降水测量原理 (24)PTU 测量原理 (25)加热（可选） (26)第 4 章安装 (27)打开变送器包装 (27)选择位置 (27)安装过程 (29)安装 (29)安装到竖立的桅杆上 (30)用安装套件安装（可选） (30)安装到水平横臂上 (32)WXT520 接地 (33)VAISALA________________________________________________________________________1操作手册_________________________________________________________________________使用套管和接地套件接地 (33)航海接地跳线 (34)对准 WXT520 (36)罗盘对准 (36)风向偏移 (37)第 5 章配线和电源管理 (39)电源 (39)使用 8 针 M12 接头配线 (42)外部配线 (42)内部配线 (43)使用螺纹接线端子配线 (44)数据通信接口 (46)电源管理 (47)第 6 章连接选项 (49)通信协议 (49)连接电缆 (50)安装 USB 电缆驱动程序 (51)服务电缆连接 (51)通过 M12 底部接头或螺纹接线端子连接 (52)通信设置命令 (53)检查当前通信设置 (aXU) (53)设置字段 (54)更改通信设置 (aXU) (55)第 7 章获取数据信息 (59)常规命令 (60)重置 (aXZ) (60)降水计数器重置 (aXZRU) (61)降水强度重置 (aXZRI) (61)测量重置 (aXZM) (62)ASCII 协议 (63)缩写和单位 (63)设备地址 (?) (64)确认活动命令 (a) (65)风数据信息 (aR1) (66)压力、温度和湿度数据信息 (aR2) (67)降水数据信息 (aR3) (67)监控方数据信息 (aR5) (68)组合数据信息 (aR) (69)合成数据信息查询 (aR0) (70)2___________________________________________________________________M210906ZH-C________________________________________________________________________________使用 CRC 轮询 (70)自动模式 (72)自动合成数据信息 (aR0) (73)SDI-12 协议 (73)地址查询命令 (?) (74)确认活动命令 (a) (75)更改地址命令 (aAb) (75)发送标识命令 (aI) (76)开始测量命令 (aM) (77)包含 CRC 的开始测量命令 (aMC) (78)开始并行测量 (aC) (78)包含 CRC 的开始并行测量 (aCC) (79)发送数据命令 (aD) (80)aM、aC 和 aD 命令示例 (81)连续测量 (aR) (83)包含 CRC 的连续测量 (aRC) (84)开始验证命令 (aV) (84)NMEA 0183 V3.0 协议 (84)设备地址 (?) (85)确认活动命令 (a) (85)MWV 风速和风向查询 (86)XDR 变换器测量查询 (88)TXT 文本传输 (95)自动模式 (95)自动合成数据信息 (aR0) (96)第 8 章传感器和数据信息设置 (97)风传感器 (97)检查设置 (aWU) (97)设置字段 (98)更改设置 (aWU) (100)压力、温度和湿度传感器 (102)检查设置 (aTU) (102)设置字段 (103)更改设置 (aTU) (104)降水传感器 (105)检查设置 (aRU) (105)设置字段 (106)更改设置 (aRU) (109)监控方信息 (111)检查设置 (aSU) (111)设置字段 (111)更改设置 (aSU) (112)合成数据信息 (aR0) (113)VAISALA________________________________________________________________________3操作手册_________________________________________________________________________第 9 章维护 (115)清洁 (115)更换 PTU 模块 (115)工厂校准和维修服务 (117)Vaisala 服务中心 (117)第 10 章故障排除 (119)自检 (121)错误信息/文本信息 (121)雨传感器和风传感器加热控制 (122)工作电压控制 (123)技术支持 (123)第 11 章技术规格 (125)性能 (125)输入和输出 (128)工作环境 (128)材料 (129)概述 (129)选项和附件 (130)尺寸 (mm/inch) (131)附录A网络 (135)在同一总线上连接多个 WXT520 (135)SDI-12 串行接口 (135)配线 (135)通信协议 (135)RS-485 串行接口 (136)配线 (136)通信协议 (136)ASCII 轮询 (137)NMEA 0183 v3.0 查询 (137)使用 ASCII 查询命令的 NMEA 0183 v3.0 查询 (139)4___________________________________________________________________M210906ZH-C________________________________________________________________________________附录BSDI-12 协议 (143)SDI-12 电子接口 (143)SDI-12 通信协议 (143)SDI-12 计时 (144)附录CCRC-16 计算 (147)将 CRC 编码为 ASCII 字符 (148)NMEA 0183 v3.0 校验和计算 (148)附录D风测量平均值方法 (149)附录E出厂配置 (151)常规设备设置 (151)风配置设置 (152)PTU 配置设置 (152)雨配置设置 (152)监控方设置 (153)VAISALA________________________________________________________________________5操作手册_________________________________________________________________________插图列表图1Vaisala 气象变送器 WXT520 (15)图2气象变送器 WXT520 的主要部件 (17)图3剖视图 (18)图4变送器底部 (19)图5安装套件（可选） (20)图6USB 电缆（可选） (20)图7鸟刺套件（可选） (21)图8浪涌保护器（可选） (22)图9加热控制 (26)图 10位于开阔空间中时建议的桅杆位置 (28)图 11位于建筑物顶部时建议的桅杆长度 (28)图 12固定螺钉的位置 (30)图 13使用可选安装套件将 WXT520 安装到桅杆上 (31)图 14将 WXT520 安装到横臂上（左视图） (32)图 15横臂上安装螺栓的位置 (33)图 16使用套管和接地套件接地 (34)图 17接地跳线的位置 (35)图 18磁偏角的简图 (36)图 19风向偏移 (37)图 20平均工作电流消耗量（对于 4Hz 风传感器采样） (40)图 21加热电流和功率与 Vh (41)图 228 针 M12 接头的针脚 (42)图 23内部配线 (43)图 24螺纹接线端子排 (44)图 25数据通信接口 (46)图 26更换 PTU 模块 (116)图 27全温度量程精确度 (126)图 28WXT520 尺寸（侧视图） (131)图 29WXT520 尺寸（俯视图和仰视图） (132)图 30安装套件尺寸 (133)图 31计时图 (145)图 32风测量平均值方法 (150)6___________________________________________________________________M210906ZH-C________________________________________________________________________________表格列表表1WXT520 串行接口和电源的针脚输出 (42)表2WXT520 串行接口和电源的螺纹接线端子针脚输出 (45)表3可用的串行通信协议 (49)表4连接电缆选件 (50)表5M12/螺纹接线端子的默认串行通信设置 (52)表6缩写和单位 (63)表7测量参数的变换器 ID (90)表8变换器表 (94)表9数据验证 (119)表 10通信问题 (120)表 11错误信息/文本信息表 (121)表 12气压 (125)表 13气温 (125)表 14风 (126)表 15相对湿度 (127)表 16降水 (127)表 17输入和输出 (128)表 18工作环境 (128)表 19电磁兼容性 (129)表 20材料 (129)表 21概述 (129)表 22选项和附件 (130)表 23常规设备设置 (151)表 24风配置设置 (152)表 25PTU 配置设置 (152)表 26雨配置设置 (152)表 27常规设备设置 (153)VAISALA________________________________________________________________________7操作手册_________________________________________________________________________本页故意保留空白。

Vaisala Weather Transmitter WXT520 Access to Real Time Weather DataThe WXT520 has an automatic control circuit that switches the heating on at low temperatures.Features/Benefi ts ▪Measures 6 most essential weather parameters ▪Accurate and stable ▪Low power consumption – works also with solar panels ▪Compact, light-weight ▪Easy to install with one-bolt mounting method ▪No moving parts ▪Heating available ▪Vaisala Confi guration T ool for pc ▪USB connection ▪IP66 housing with mounting kit ▪Applications: weather stations, dense networks, harbors, marinas Measuring acoustic precipitation The WXT520 precipitation measurement is based on the unique Vaisala RAINCAP ® Sensor, which detects the impact of individual rain drops. The signals exerting from the impacts are proportional to the volume of the drops. Hence, the signal from each drop can be converted directly to the accumulated rainfall.The WXT520 measures accumulated rainfall, rain intensity and duration of the rain — all in real time. The Vaisala RAINCAP ® Sensor is the only maintenance-free precipitation sensor on the market.WXT520The Vaisala Weather TransmitterWXT520 measures barometricpressure, humidity, precipitation,temperature, and wind speed and direction.To measure wind speed anddirection, the WXT520 has theVaisala WINDCAP ®sensor that usesultrasound to determine horizontalwind speed and direction.The array of three equally spacedtransducers on a horizontal plane isa Vaisala speci c design. Barometricpressure, temperature, and humiditymeasurements are combined in the PTU module using capacitivemeasurement for each parameter.It is easy to change the modulewithout any contact with thesensors.The WXT520 is immune to oodingclogging, wetting, and evaporationlosses in the rain measurement.Technical dataLiquid precipitationRainFall cumulative accumulation after the latest automatic or manual reset output resolutions and units 0.01 mm, 0.001 inches accuracy 5%*RainFall duRation counting each ten-second increment whenever water droplet is detectedoutput resolution and unit 10 s Rain intensity one-minute running average in ten-second steps range 0 ... 200 mm/h (broader range with reduced accuracy)output resolutions andunits 0.1 mm/h, 0.01 inches/h Hail cumulative amount of hits against the collecting surface output resolutions and units 0.1 hits/cm2, 0.01 hits/in2, 1 hits Hail duRation counting each ten-second increment whenever hailstone is detected output resolution and unit 10 s Hail intensity one-minute running average in ten-second steps output resolutions and units 0.1 hits/cm2h, 1 hits/in2h, 1 hits/h* Due to the nature of the phenomenon, deviations caused by spatial variations may exist in precipitation readings, especially in a short time scale. The accuracy specification does not include possible wind induced errors.Wind speed range 0 ... 60 m/s response time 250 ms accuracy0 ... 35 m/s ±0.3 m/s or ±3%, whichever is greater 35 m/s ... 60 m/s ±5%output resolutions and 0.1 m/s, 0.1km/h, units 0.1 mph, 0.1 knots diRection azimuth 0 ... 360°response time 250 ms accuracy ±3°output resolution and unit 1°Air temperatureRange -52 ... +60 °C (-60 ... +140 °F)Accuracy for sensor at +20 °C ±0.3 °C (±0.5 °F)Accuracy over temperature range (see graph below)Barometric pressureRange 600 ... 1100 hPaAccuracy ±0.5 hPa at 0 ... +30 °C (+32 ... +86 °F)±1 hPa at -52 ... +60 °C (-60 ... +140 °F)Output resolutions and units 0.1 hPa, 10 Pa, 0.0001 bar, 0.1 mmHg, 0.01 inHgRelative humidityRange 0 ... 100 %RH Accuracy ±3 %RH within 0 ... 90 %RH±5 %RH within 90 ... 100 %RHOutput resolution and unit 0.1 %RHGeneralOperating temperature -52 ... +60 °C (-60 ... +140 °F)Storage temperature -60 ... +70 °C (-76 ... +158 °F)Operating voltage 5 ... 32 VDC Typical power consumption 3 mA at 12 VDC (with defaults) Heating voltage 5 ... 32 VDC (or AC, max. 30 VRMS)Serial data interface SDI-12, RS-232, RS-485, RS-422,USB connection, Weigth 650 g (1.43 lb)Housing IP65Housing with mounting kit IP66Output resolutions and units 0.1 °C, 0.1 °F Ref. B210417en-e ©Vaisala 2009this material is subject to copyright protection, with allcopyrights retained by Vaisala and its individual partners. allrights reserved. any logos and/or product names are trademarksof Vaisala or its individual partners. the reproduction, transfer,distribution or storage of information contained in this brochurein any form without the prior written consent of Vaisala is strictlyprohibited. all specifications — technical included — are subjectto change without notice.Electromagnetic compatibilityComplies with EMC standardEN61326-1; IndustrialEnvironment IEC standards IEC 60945/61000-4-2 ... 61000-4-6。

青海省自动气象站测试命令说明
根据省局观测网络处要求，青海省大气探测技术保障中心给各州（地、市、县）气象局配发了MILOS500型、CAWS600型和ZQZ型自动站测试线，为便于各州（地、市、县）气象局做好自动站保障维护工作，现将三种类型自动站主要测试命令描述如下：
一、MILOS500型自动站
建议测试软件使用超级终端，通讯参数是9600，n，8，1，输入以下命令：
CLI（回车） /盲打
SYSTEM（回车） /进入SYSTEM目录
SYSTEM> TYPE D：120317.LOG /显示2012年3月17日的数据SYSTEM>CLOSE /退出
二、CAWS600型自动站
建议测试软件使用超级终端或sscom32，通讯参数是9600，n，8，1，输入以下命令：
D（回车） /显示日期
T（回车） /显示时间
TEST（回车） /当收到PASS字符，说明自动站运行正常。

3CV /风速瞬时值
4CV /风向瞬时值
22CV /1分钟雨量
30CV /气温瞬时值
36CV /相对湿度瞬时值 84CV /气压瞬时值
44CV /地表温瞬时值
50CV /5cm地温瞬时值 51CV /10cm地温瞬时值 52CV /15cm地温瞬时值 53CV /20cm地温瞬时值三、ZQZ型自动站
建议测试软件使用超级终端或sscom32，（1）、ZQZ-A型：通讯参数是4800，e，8，1
test（回车）显示各要素的瞬时值（2）、ZQZ-BH型：通讯参数是9600，n，8，1
Samples（回车）显示各要素的瞬时值
注：若有什么疑问或建议，请打自动站故障台电话。

/FM-yc远程自动气象站一、FM-yc远程自动气象站简介：FM-yc远程自动气象站有数据采集器、传感器、安装支架、软件等部分组成，是一套完整的气象监测系统，采集方式和数据存储符合国际气象组织要求。

既可作为小气候监测也可以作为气象观测，集多种测量参数于一体。

二、FM-yc远程自动气象站特点：1、通讯方式灵活多样，用户可以使用自备的笔记本计算机操作，在条件允许的情况下可以使用电话网络，也可以选择GSM无线通信方式，实现远程管理数据，采集器支持GPRS、GSM、wifi等无线传输方式，同时可支持高性能100M 网卡支持100/10M自适应，实现数据的远程控制和传输。

2、RAM: 1GB;ROM：16GB，带有一个标准的SD卡座，可扩展到64GB。

通SD卡或U盘即可导出历史数据到电脑上进行二次分析，无需连接软件。

3、自动气象站采用IP65防护等级设计，主机采用7寸高灵敏度液晶触摸屏显示，核心处理器采用S3C2416XH-40, ARM926EJ,主频为400MHZ，采用高密度沉金工艺来充分保证高速信号的完整性和稳定性。

支持多种尺寸TFT彩/ 色液晶和LED显示屏等的实时显示。

同时兼容本公司所有的RS485传感器，用户可根据自身需要自由搭配传感器，采集器内置了多种传感器的标定曲线，无需人工编程，即可自己设定各种传感器，省去了不必要的麻烦。

4、用户通过液晶屏幕即可自由设定采集时间间隔，省去了以往连接软件设定的麻烦。

5、高性能稳压电路，支持DC9～24V输入电源支持反接、抗脉冲群、抗雷、抗静电等保护。

内部集成实时时钟(RTC时钟电源3V)电池断电后可以运行5年以上，保证时间的准确性，板载1个蜂鸣器，可用于警报或者提示发声等。

6、安装维护方便，性能稳定，可靠性高，故障率低，可扩展性强，系统程序采用模块化结构，方便功能扩展或屏蔽以及各种传感器的接入。

7、自动气象站管理软件可在WINDOWS2000以上环境即可运行并支持最新WIN8操作系统，实时显示各路数据，每隔10秒更新一次，每组数据自动存储(存储时间可以设定)，与打印机相连自动打印存储数据，生成标准气象图文报表及统计分析曲线,存储量达数年以上，数据存储格式为EXCEL标准格式可供其它软件调用，并可以将数据上传至专业的网站进行实时更新便于查询。

Science &Technology Vision 科技视界※基金项目:公益性行业(气象)科研专项“地面观测网自动化运行监控技术研究”(GYHY201006052)。

作者简介:牛超(1984—),男,山东淄博人,本科,助理工程师,从事气象探测业务工作。

0引言20世纪70年代,美国空军开始在航空设备中设计并安装机内测试设备—BITE 技术,如著名的F-18战斗攻击机,该机型于1978年11月18日首飞,其雷达系统内部安装可识别和隔离故障的测试设备(BITE)[1]。

至今BITE 技术在国外已得到迅速发展,逐步扩大到各个技术领域,已经形成一门与可靠性、维修性并行发展的学科分支。

作为一门新兴学科,我国在该方面的研究起步较晚,近些年来,有关部门已经开展了不少的研究工作,在装备研制中提出了测试性要求,开展了有关保障方面的工程设计工作。

1BITE 技术内置测试设备BITE(Built in Test Equipment)是从航空领域发展起来的一种设备内部自动测试技术[2]。

随着大规模集成电路和计算机技术的广泛应用,硬件设备和软件系统在提高性能的同时,也大大增加了设备的复杂性,这对设备的维修性和可靠性有很大影响。

BITE 技术的出现,可以快速地检测该设备的故障,缩短故障检测与维修时间,提高其可靠性与安全性。

国外如芬兰VAISALA 公司,英国COMPBELL 公司和澳大利亚DATATALKER 公司,都是气象行业内提供专业先进设备的领先公司,其采集器内置基本的数据质量监控功能,结合自检和诊断命令,提供状态数据,必要时可以提供交互式的测试和服务命令来确诊故障。

我国现有业务观测使用的地面自动气象站设备本身还缺少内置检测装置(BITE)和自检系统,因此无法实现设备运行状态信息自动化,目前仅是基于自动气象站观测数据、辅以人工分析来判定设备运行状态,不能实时科学地反映设备运行情况和快速检测故障部位和原因。

2WUSH-AUTO 型自动气象站简介WUSH-AUTO 型自动气象站由中国气象局气象探测中心、江苏省无线电科学研究所有限公司联合研制,在现有自动气象站基础上完成BITE 电路设计,通过对自动气象站运行状态的实时监控和综合判断,实现自动气象站传感器及关键部件的故障自动检测和诊断。

WX Ultrasonic WeatherStation® Instruments for Marine ApplicationsAIRMAR’s best-in-class, all-in-one solution for real-time, site-specific weather informationWX SeriesAvailable Models: 120WX, 220WX From racing and cruising sailboats to yachting and commercial fishing, Airmar has WeatherStation®products specifically designed for your marine application.The WX Series WeatherStationi nstruments meet a growing need for real-time, s ite-specific weather i nformation. For a pplications where true and apparent wind are i mportant, the 220WX is r ecommended and includes a 10Hz GPS, three- a xiss olid-state compass, rate gyro and tilt sensors. This model f eaturesc onfigurable NMEA 0183 and NMEA2000® digital data outputs, p roviding u nparalleled versatility for all your weather monitoring needs.Both models offer a truly best-in-class s olution at a better price point than any other weather monitoring system on the market today.FEATURES• W eatherStation® instruments combine up to seven sensors, all with no m oving parts, in one compact unit • W ind readings are not affected by the common problems known in mechanical a nemometers and weather measuring devices like bearing wear, salt and dirt b uild-up, or bird perching, which can all result in failure or data inaccuracy • U nits are easy-to-install either permanently, or as a portable s ystem.They can be installed on a standard pole with 1”-14 UNS or 3/4” NPT threads.• I PX6 waterproof rating (units with the relative humidity option added are IPX4 waterproof rated)• O ptional heater model available for colder climates under 1° C • O perating voltage range of 12-24 VDCActual SizeMARINE APPLICATIONSProduct Models to Satisfy Multiple Weather Needs120WX220WXNow available on iTunes — OnSiteWXThe innovative App for real-time weather data!DATA OUTPUT PROTOCOLNMEA 0183 Sentence Structure$GPDTM ........GPS Datum Reference $GPGGA ........GPS Fix Data$GPGLL ..........Geographic Position—Latitude and Longitude $GPGSA .........GNSS DOP and Active Satellite $GPGSV .........Satellites in View$GPRMC ........Recommended Minimum GNSS $GPVTG .........COG and SOG $GPZDA .........Time and Date$HCHDG ........Heading, Deviation, and Variation $HCHDT ........True Heading$HCTHS .........True Heading and Status $TIROT ...........Rate of Turn$WIMDA ........Meteorological Composite $WIMWD .......Wind Direction and Speed $WIMWV. ......Wind Speed and Angle$WIMWR .......Relative Wind Direction and Speed $WIMWT .......True Wind Direction and Speed $YXXDR .........Transducer Measurements NMEA2000® Output Message Structure 59392 .............ISO Acknowledgement 060928...........ISO Address Claim12620 .............Acknowledge Group Function 126464...........PGN List 126992...........System Time126996...........Product Information126998...........Configuration Information 127250...........Vessel Heading 127251...........Rate of Turn 127257...........Attitude127258...........Magnetic Variation129025...........Position and Rapid Update 129026...........COG and SOG, Rapid Update 129029...........GNSS Position Data 129033...........Time and Date 129044...........Datum129538...........GNSS Control Status 129539...........GNSS DOPs129540...........GNSS Sats in View 130306...........Wind Data130310...........Environmental Parameters 130311...........Environmental Parameters 130312...........Temperature 130313...........Humidity130314...........Actual Pressure130323...........Meteorological Station DataSPECIFICATIONSWind Speed Range:— 0 knots to 78 knots (0 MPH to 90 MPH, 0 m/s to 40 m/s)Wind Speed Resolution:— 0.1 knot (0.1 MPH, 0.1 m/s)Wind Speed Accuracy @ 0°C to 55°C (32°F to 131°F), no precipitation*:— Low Wind Speeds:0 -10 knots; 1 knot RMS +10% of reading(0 MPH to 11.5 MPH; 1.1MPH + 10% of reading)(0 m/s to 5 m/s; 0.5 m/s + 10% of reading)— High Wind Speeds:10-78 knots; 2 knots RMS or 5%, whichever is greater(11.5 MPH to 90 MPH; 2.3 MPH or 5%, whichever is greater)(5 m/s to 40 m/s; 1 m/s or 5%, whichever is greater)Wind Speed Accuracy in wet conditions**:— 5 knots RMS (5.7 MPH RMS, 2.5 m/s RMS)Wind Direction Range: 0° to 360°Wind Direction Resolution: 0.1°Wind Direction Accuracy @ 0°C to 55°C (32°F to 131°F), no precipitation*:— Low Wind Speeds (5° RMS typical):4 -10 knots (4.6 MPH to 11.5 MPH, 2 m/s to 5 m/s)— High Wind Speeds (2° RMS typical):> 10 knots (>11 .5 MPH, >5 m/s)Wind Direction Accuracy in wet conditions** (8° RMS Typical):>8 knots (>9.2 MPH, >4 m/s)Compass Accuracy:— 1° static heading accuracy; 2° dynamic heading accuracy—220WX only Pitch and Roll Range / Accuracy: ±50° / <1°—220WX Air Temperature Range***: -40°C to 55°C (-40°F to 131°F)Air Temperature Resolution: 0.1°C (0.1°F)Air Temperature Accuracy:±1.1°C (±2°F)* @ >4 knots wind (>4.6 MPH wind) (>2 m/s wind)Barometric Pressure Range:300 mbar to 1100 mbar (24 inHg to 33 inHg, 800 hPa to 1100 hPa)Barometric Pressure Resolution: 0.1 mbar (0.029 inHg, 0.1 hPa)Barometric Pressure Accuracy:±1 mbar (±0.029 inHg, ±1 hPa) when altitude correction is available Relative Humidity Range: 10% to 95% RH Relative Humidity Accuracy*: ±5% units RH GPS Position Accuracy:3 m (10’) with WAAS/EGNOS (95% of the time)—220WXOperating Temperature Range: -25°C to 55°C (-13°F to 131°F)Heater Operating Temperature Range: -40°C to 55°C Heater cycles on when sensor reaches 1°C Supply Voltage: 12 VDC to 24 VDC Heater Supply Voltage: 24 VDC Supply Current (@ 12 VDC):—(<85 mA) <1.0W, LEN 2 —120WX — (<165 mA) <2.0W, LEN 4 —220WX Supply Current (@ 24 VDC):— (<42 mA) <1.0W —120WX — (<85 mA) <2.0W —220WXHeater Supply Current (@ 24 VDC):— (2.5 A) <60WWeight: 300 grams (0.8 lb)Communication Interface: NMEA 0183 (RS422) and NMEA2000® (CAN bus)****Mounting Thread Size on Base: 1”-14 UNS or 3/4” NPT Certifications and Standards:CE, IPX6 (Relative Humidity/IPX4), RoHS, IEC60945RMS—Root Mean Square LEN—Load Equivalency Number*When the wind speed is less than 2 m/s (4.6 MPH) and/or air temperature is below 0°C (32°F), wind, temperature, and relative humidity readings will be less accurate.**Wet conditions include moisture, rain, frost, dew, snow, ice and/or sea spray in the wind channel.***Temperature and relative humidity reports invalid during heater operation.****Airmar has made the address claiming modifications to enable compatibility with the ISO 11783c ommunication protocol for the agriculture industry – that is based on the SAE J1939 protocol.PART NUMBERS120WX: 44-858-1-01, NMEA 0183 (RS422) or NMEA2000® (CAN Bus)220WX: 44-854-1-01, NMEA 0183 (RS422) or NMEA2000® (CAN Bus)Field Serviceable RH Module: 33-627-02120WXH w/heater: 44-852-1-01, NMEA 0183 (RS422)1, 2, 3220WXH w/heater: 44-856-1-01, NMEA 0183 (RS422)1, 2, 31 Relative Humidity (RH) not available on heater models2 Cables sold separately 3Heater requires 24VDC@2015 Airmar Technology Corporation WX_Series_MARINE_APP_rB 11/01/15As Airmar constantly improves its products, all specifications are subject to change without notice. All Airmar products are designed to provide high levels of accuracy and reliability, however they should only be used as aids to navigation and not as a replacement for traditional navigation aids and techniques. WeatherStation® and W eatherC aster TM are registered trademarks and trademarks of Airmar Technology Corporation. Other company or product names mentioned in this document may betrademarks or registered trademarks of their respective companies, which are not affiliated with Airmar.Performing Above and Beyond Competitive Products on the MarketVirtually all mechanical and ultrasonic anemometers report apparent wind speed and direction. The Airmar WX Series is unique because it calculates both true and apparent wind speed and direction. When the WX S eries is mounted on a moving vessel, the apparent wind is the wind you would feel on your hand if you held it out while moving. Since the WX Series has a built in GPS and compass, it calculates the true wind speed and direction based upon the apparent wind, speed of the vessel, and vessel heading.True wind information is significant for numerousa pplications. True wind speed and direction is also m ission-critical. When en route to an e mergency s ituation, the Coast Guard, who ensures the safety, security ands tewardship of the Nation’s waters, can use the true wind readings to p redict wind conditions at the disaster site before they even a rrive, p roviding vital information for i ncident response and disaster management in the m aritime environment.Understanding True and Apparent Wind。