HLMP-C317-M0001中文资料

10000 机床轴名称10160 与MMC 通讯的系数10002 NCK 机械轴的逻辑图10165 预留：10008 PLC 控制的轴的最大号码10170 MMC 任务的启动时间限制10010 方式组的通道有效10180 MMC 任务到准备任务的系数10050 基本系统循环时间10185 NCK 运行时间分量10059 Profibus 报警标识符只对内部10190 模拟的换刀时间10060 位置控制循环系数10192 齿轮换挡时间10061 位置控制循环10200 线性位置的计算精度10062 位置控制循环延迟10210 角度位置的计算精度10065 位置设定延迟10220 激活比例系数10070 插补运算器的周期系数10230 机床数据比例系数10071 插补循环10240 基本公制长度单位10072 通讯任务周期的系数10250 INCH 的转换系数10074 PLC 任务比插补任务的系数10260 有效转换的基本设定10075 PLC 循环时间10270 位置表的比例系统10080 取样实际值分配系数10280 对rel.6.3 的比较gt和lt兼容10082 速度设定输出的超前时间10284 不同的显示变量方式10083 位置控制器输出保持时间的偏置10290 OEM 刀具数据的物理单位10085 中断程序段监控时间失效-激活10291 SIEMENS-OEM 刀具数据的单位10088 重新启动延迟10292 OEM 刀沿数据的物理单位10089 缺少总线时脉冲抑制的等待时间10293 SIEMENS-OEM 刀沿数据的单位10090 监控周期的系数10300 NCK 的模拟输入数10091 检查周期时间的显示10310 NCK 的模拟输出数10092 安全数据再确认循环时间显??10320 NCK 模拟输入的比例10093 SPL 文件存取号10330 NCK 模拟输出的比例10094 安全报警禁用级10340 预留：10095 安全方式屏蔽10350 NCK 数字输入字节的数量10096 安全诊断功能10360 NCK 数字输出字节的数量10097 对于SPL-差额停止反应10361 开关量输入输出短路10098 PROFIsafe 通讯的系数10362 NCK 模拟输入的配置10099 PROFI 安全通讯循环时间10364 NCK 模拟输出的配置10100 最大PLC 周期10366 NCK 数字输入配置10110 PLC 确认的平均时间10368 NCK 数字输出的配置10120 PLC 启动的监控时间10380 更新NCK I/O 设备10130 与MMC 通讯的时间限制10382 NCK 外设的引导时间10131 过载时屏幕更新处理10384 NCK I/O 的处理10132在零件程序中监控时间MMC 命令10385 PROFI 安全-地址主控-设备10134 同时发生的MMC 节点数量10386 PROFI 安全-地址输入-设备10136 PCS 位置的显示方式10387 PROFI 安全-地址输出-设备10140 与驱动通讯的时间限制10388 输入分配A_INSE 到PROFIsafe-de10150 与驱动通讯的系数10389 输出分配A_OUTSE 到PROFIsafe-de10390 SPL 外部接口的输入分配10648 底角的名称10392 SPL 外部接口的输出分配10650 插补参数的名称10394 可直接在NC 读取的PLC 输入字节数量10652 定义轮廓角度名称10395 直接读PLC 输入位起始地址10654 定义轮廓半径名称10396 可直接在NC 写入的PLC 输入字节数量10656 定义轮廓斜面名称10397 直接写PLC 输出位起始地址10660 G2/G3 中间坐标点的名称10398 PLCIO 输入循环升级时间10670 位置信息名称10399 用于PLCIO 左最高位/右最高位10672 轴位置信息名称10400 编辑循环输入字节数量10674 多项式编程不带G 功能POLY 编程10410 编译循环输出字节数10700 程序预处理阶段10420 编译循环的NCK 输出10702 块信号停止预防10430 编辑循环的硬件调试屏蔽10704 空运行激活10450 分配软件凸轮到机床轴10706 跳越有效10460 负凸轮1 - 1632的时间响应10707 编程测试模式10461 正凸轮 1 - 1632的时间响应10708 程序段搜索模式10470 I/O 设备上 1 - 8 凸轮的配置10710 更新的设定数据10471 I/O 设备上9 -16 凸轮的配置10712 未配置的NC 代码列表10472 I/O 设备上17 - 24 凸轮的配置10713 带预处理停止的M 代码10473 I/O设备上25 - 32 凸轮的配置10714 复位后M 代码 f.主轴激活10480 NCU 凸轮信号输出的屏蔽10715 M 代码由子程序代替10485 凸轮特性10716 M 代码替换的子程序名称10490 测量的软挡块10717 T 代码替换的子程序名称10530 比较器字节 1 的模拟量输出10718 带参数的M 代码替代10531 比较器字节2 的模拟量输出10719 T 功能替换的参数化10540 比较器字节1 的参数化10720 上电操作方式10541 比较器字节2 的参数化10722 参数更改10600 FRAME框架旋转的输入类型10730 手动JOG键的功能10602 几何轴转换的FRAME 10731 手动JOG键的功能10604 改变几何轴的工作区限制10760 G53，G153，SUPA 的说明10610 镜象参考轴10780 删除TP 编辑启动禁止10612 镜象改变10800 第一M 功能通道同步10613 NCU 全局基础FRAME 复位后激活10802 通道同步的最后M 功能10615 上电后复位全局基础FRAME 10804 M 功能激活ASUP10617 在子程序存储时FRAME 行为10806 M 功能没激活ASUP10618 GEO 轴变化的保护范围10808 中断程序激活ASUP10620 欧拉角的名称10810 G31 P 测量信号结构10630 普通矢量的名称10812 带G68 双刀架10640 方向矢量的名称10814 MACRO 调用的M 功能10642 旋转矢量的名称10815 M 功能macro 调用的子程序名称10644 临时矢量的名称10816 macro 调用的G 功能10646 第二路径方向编程名称10817 G 功能macro 调用的子程序名称10818 ASUP 启动M96的中断数11380 安全集成测试机床数据10820 快速返回的中断数G10.6 11382 地址单元的INTEGER 整数显示10850 OEM-G-代码的最大号码11384 地址单元的REAL 显示10880 合适的CNC 系统定义11386 地址单元的INTEGER 整数输入10881 ISO_3 模式：G 代码系统11388 地址单元的REAL 输入10882 外部NC 语言的用户G 代码表11390 地址单元的内容重写10884 带或不带数值运算命令11398 轴变量服务器出错10886 增量系统11400 激活内部轨迹功能10888 刀具的位置号11410 报警输出的屏蔽10890 外部语言的刀具编程模式11411 报警激活10892 G00 插补11412 报警响应CHAN_NOREADY 有效10900 分度轴表1 位置数11413 报警参数作为文本输出10910 分隔位置表1 11420 记录文件大小KB10920 分度轴表 2 的位置数11430 数字化时的通道定义10930 分隔位置表2 11432 选择3 轴或32 轴数字化11100 辅助功能组的辅助功能数量11450 参数化搜索11110 辅助功能组说明11460 异步往复的模式表单11120 程序全局用户数据PUD系数有效11470 重新配置的属性11140 除GUD 模块以外的地址11480 OB1 中PLC 轨迹数据的缓存深度11200 上电时装载标准数据11481 OB35 中PLC 轨迹数据的缓存深度11210 仅保存修改过的机床数据11482 OB40 中PLC 轨迹数据的缓存深度11220 INI 初始化文件出错时的系统反应11500 受保护的同步动作11230 MD 文件备份的结构11510 最大允许的IPO 负载11240 SDB1000 号11600 固定的BAG 响应11250 Profibus 停机处理11602 ASUP 运行时不考虑停止的原因11270 NC 语言元素的默认值激活11604 ASUP_START_MAS 优先级有效11280 在工件目录处理INI 文件11610 用户定义ASUP 程序激活11290 在DRAM 选择目录11612 用户定义ASUP 编程的保护级11291 DRAM 中选择目录11620 PROG_EVENT 的程序名称11295 记录文件的存储类型11640 使能间隔在MD11300 JOG 方式中的INC 和REF MC_AXCONF_MACHAX_USED11310 方向改变手轮的阀值11649 打开在＃MC_AXCONF_MACHAX_USED 中的11320 每个间隔位置的手轮脉冲数保护11322 每个凸轮爪位置的轮廓手轮脉冲11660 可能的电子齿轮箱数量11324 手轮号码在VDI 接口中描述11700 NC 卡代码11330 INC/手轮的增量大小12000 轴进给倍率开关编码11340 第三手轮：驱动类型12010 轴进给倍率系数11342 第三手轮：驱动号/测量电路号12020 灰度- 编码轨迹进给率开关11344 第三手轮：输入模块／测量电路12030 路径进给倍率的系数11346 手轮：12040 灰度码快速运行倍率开关11360 INC 信号影响方式组12050 快速进给的倍率系数12060 灰度码主轴倍率开关13030 模块识别12070 主轴倍率的系数13040 驱动类型12080 回参考点速度的倍率13050 逻辑驱动地址12082 进给倍率13060 Profibus-DP 标准通讯类型12100 二进制编码的倍率限定13070 使用DP 功能12200 在倍率0 时运行13080 驱动类型Profibus12202 直线轴的固定进给率13100 诊断驱动母线12204 旋转轴的固定进给率13200 探头极性改变12205 主轴固定转速13201 带数字输出的测量脉冲模拟12510 在NCU 组中的NCU 代码13210 带Profibus 驱动的测头操作类型12520 NCU 号，总线终止阻抗有效13220 探头延迟时间12540 联接总线波特率14000 SSI 绝对值编码器的波特率12550 信息存储区重复的最大量14010 FIPO 启动延迟12701 在轴系列1 中的轴清单14020 SSI 延时12702 在轴系列 2 中的轴清单14500 输入字节的个数从PLC12703 在轴系列3 中的轴清单14502 输出字节的个数到PLC12704 在轴系列4 中的轴清单14504 用户数据的号INT12705 在轴系列5 中的轴清单14506 用户数据的号HEX12706 在轴系列 6 中的轴清单14508 用户数据的号FLOAT12707 在轴系列7 中的轴清单14510 用户数据INT12708 在轴系列8 中的轴清单14512 用户数据HEX12709 在轴系列9 中的轴清单14514 用户数据FLOAT12710 在轴系列10 中的轴清单14516 用户数据HEX12711 在轴系列11 中的轴清单17200 全局MMC 信息没有物理单元12712 在轴系列12 中的轴清单17201 全局MMC 状态信息没有物理单元12713 在轴系列13 中的轴清单17500 替换刀具的最大号12714 在轴系列14 中的轴清单17510 卸载后刀具- 数据的运行状态12715 在轴系列15 中的轴清单17520 产生新刀具：默认设置12716 在轴系列16 中的轴清单17530 对于HMI 标记的刀具-数据-变化12750 轴系列名称17600 REORG 中log 存储最优化深度12970 数字PLC 输入地址的起始地址18000 更新PLC 接口12971 数字输入地址号18040 PCMCIA 卡的版本和日期12974 数字PLC 输出地址的起始地址18050 自由无缓冲内存bytes12975 数字输出地址号18060 自由缓冲内存bytes。

LM3173-TERMINAL ADJUSTABLE REGULATORDescriptionThe LM317 is an adjustable three-terminal positive-voltage regulator capable of supplying more than 1.5A over an output-voltage range of 1.2 V to 37 V. It is exceptionally easy to use and requires only two external resistors to set the output voltage. Furthermore, both line and load regulation are better than standard fixed regulators.In addition to having higher performance than fixed regulators, this device includes on-chip current limiting, thermal overload protection, and safe-operating-area protection. All overload protection remains fully functional, even if the ADJUST terminal is disconnected.The LM317 is versatile in its applications, including uses in programmable output regulation and local on-card regulation. Or, by connecting a fixed resistor between the ADJUST and OUTPUT terminals, the LM317 can function as a precision current regulator. An optional output capacitor can be added to improve transient response. The ADJUST terminal can be bypassed to achieve very high ripple-rejection ratios, which are difficult to achieve with standard three-terminal regulators.1、Output Voltage Range Adjustable From1.2 V to 37 V2、Output Current Greater Than 1.5 A3、Internal Short-Circuit Current Limiting4、Thermal Overload Protection5、Output Safe-Area Compensation6、Package Options Include PlasticSmall-Outline Transistor SOT-223 (DCY),Flange Mounted (KTE) and Heat-SinkMounted (KC) PackagesAdjustable V oltage regulatorNOTES:A.Cis not required if the regulator is closed enough to the power-supply filter.inB.Coimproves transient response, but is not needed for stability.Vout is calculated as Vout=Vref(1+12RR)+(IAdj×R2)APPLICATION INFORMATIONBasic Circuit OperationThe LM317 is a 3−terminal floating regulator. In operation, the LM317 develops and maintains a nominal 1.25 V reference (Vref) between its output and adjustment terminals. This reference voltage is converted to a programming current (IPROG) by R1 (see Figure 17), and this constant current flows through R2 to ground. The regulated output voltage is given by:Vout =Vref(1+12RR)+(IAdj×R2)Since the current from the adjustment terminal (IAdj) represents an error term in the equation, theLM317 was designed to control IAdjto less than 100 A and keep it constant. To do this, all quiescent operating current is returned to the output terminal. This imposes the requirement for a minimum load current. If the load current is less than this minimum, the output voltage will rise. Since the LM317 is a floating regulator, it is only the voltage differential across the circuit which is important to performance, and operation at high voltages with respect to ground is possible.Basic Circuit ConfigurationVref=1.25V TypicalLoad RegulationThe LM317 is capable of providing extremely good load regulation, but a few precautions are needed to obtain maximum performance. For best performance, the programming resistor (R1) should be connected as close to the regulator as possible to minimize line drops which effectively appear in series with the reference, thereby degrading regulation. The ground end of R2 can be returned near the load ground to provide remote ground sensing and improve load regulation.External CapacitorsA 0.1 μF disc or 1.0 μF tantalum input bypass capacitor (Cin) is recommended to reduce the sensitivity to input line impedance. The adjustment terminal may be bypassed to ground toimprove ripple rejection. This capacitor (CAdj) prevents ripple from being amplified as the output voltage is increased. A 10 μF capacitor should improve ripple rejection about 15 dB at 120 Hz in a 10 V application. Although the LM317 is stable with no output capacitance, like any feedback circuit, certain values of external capacitance can cause excessive ringing. An output capacitance(Co) in the form of a 1.0 μF tantalum or 25 μF aluminum electrolytic capacitor on the output swamps this effect and insures stability.Protection DiodesWhen external capacitors are used with any IC regulator it is sometimes necessary to add protection diodes to prevent the capacitors from discharging through low current points into the regulator. Figure 18 shows the LM317 with the recommended protection diodes for outputvoltages in excess of 25 V or high capacitance values (Co > 25 μF, CAdj> 10 μF). Diode D1prevents Cofrom discharging thru the IC during an input short circuit. Diode D2 protects againstcapacitor CAdjdischarging through the IC during an output short circuit. The combination ofdiodes D1 and D2 prevents CAdjfrom discharging through the IC during an input short circuit. Voltage Regulator with Protection DiodesLM317—三端可调节输出正电压稳压器概述LM317是3端可调节输出正电压稳压器，在输出范围为1.2V到37V范围时能提供超过1.5A的电流。

HS3171模块安装使用手册版本1.02西安和森自动化技术有限公司2010年10月1目录第一部分：硬件操作 ---------------------------------------------------------------------------------------------2一、基本性能-------------------------------------------------------------------------------------------------------2二、引脚定义-------------------------------------------------------------------------------------------------------2三、终端电阻选择--------------------------------------------------------------------------------------------------3四、标识和速率选择------------------------------------------------------------------------------------------------3五、指示灯---------------------------------------------------------------------------------------------------------3六、外部接线-------------------------------------------------------------------------------------------------------5七、恢复出厂设置--------------------------------------------------------------------------------------------------6八、模块安装 ------------------------------------------------------------------------------------------------------6 第二部分：参数配置----------------------------------------------------------------------------------------------7一、参数说明-------------------------------------------------------------------------------------------------------7二、参数配置-------------------------------------------------------------------------------------------------------71、使用专用配置软件-----------------------------------------------------------------------------------------------72、使用一般收发软件（CAN2.0）----------------------------------------------------------------------------------8 第三部分：CANopen协议及其应用-------------------------------------------------------------------------10一、NMT协议------------------------------------------------------------------------------------------------------10二、SYNC同步协议-------------------------------------------------------------------------------------------------10三、TimeStamp协议-----------------------------------------------------------------------------------------------11四、EMCY协议-----------------------------------------------------------------------------------------------------11五、NodeGuard协议-----------------------------------------------------------------------------------------------12六、Heartbeat协议-------------------------------------------------------------------------------------------------13七、PDO协议------------------------------------------------------------------------------------------------------14八、SDO协议------------------------------------------------------------------------------------------------------17 第四部分：产品保修----------------------------------------------------------------------------------------------18附录A：对象字典清单--------------------------------------------------------------------19 附录B：预定义连接集--------------------------------------------------------------------21 附录C：CANopen协议文件--------------------------------------------------------------21 附录D：产品型号定义规范---------------------------------------------------------------222第一部分：硬件操作CAN是控制器局域网络(Controller Area Network)的简称，由德国BOSCH公司开发，由于其具有高性能、高可靠性及较好的实时性等优点现已广泛应用于工业自动化、各种控制设备、交通工具、医疗仪器以及建筑等众多领域，是国际上应用最广泛的现场总线之一，1993年11月ISO正式颁布了高速通信控制器局部网（CAN）国际标准（ISO11898），为控制器局部网标准化、规范化推广提供了保障。

LM317中文资料引脚功能应用电路简介：LM317中文资料引脚功能应用电路LM117/LM317简介LM117/LM317是美国国家半导体公司的三端可调正稳压器集成电路。

我国和世界各大集成电路生产 ...关键字：LM317LM117/LM317简介LM117/LM317是美国国家半导体公司的三端可调正稳压器集成电路。

我国和世界各大集成电路生产商均有同类产品可供选用，是使用极为广泛的一类串联集成稳压器。

LM117/LM317 的输出电压范围是1.2V 至37V，负载电流最大为1.5A。

它的使用非常简单，仅需两个外接电阻来设置输出电压。

此外它的线性调整率和负载调整率也比标准的固定稳压器好。

LM117/LM317 内置有过载保护、安全区保护等多种保护电路。

通常LM117/LM317 不需要外接电容，除非输入滤波电容到LM117/LM317 输入端的连线超过6 英寸（约15 厘米）。

使用输出电容能改变瞬态响应。

调整端使用滤波电容能得到比标准三端稳压器高的多的纹波抑制比。

LM117/LM317 能够有许多特殊的用法。

比如把调整端悬浮到一个较高的电压上，可以用来调节高达数百伏的电压，只要输入输出压差不超过LM117/LM317 的极限就行。

当然还要避免输出端短路。

还可以把调整端接到一个可编程电压上，实现可编程的电源输出。

LM117负电压输出LM317正电压输出LM317特性简介可调整输出电压低到1.2V。

保证1.5A 输出电流。

典型线性调整率0.01%。

典型负载调整率0.1%。

80dB纹波抑制比。

输出短路保护。

过流、过热保护。

调整管安全工作区保护。

标准三端晶体管封装。

电压范围LM117/LM317 1.25V 至37V 连续可调图1 LM317典型应用电路图2 LM317外形引脚图片D2PAK封装典型的TO-3封装TO-220封装ISOWATT220封装LM117LM117KLM217D2T LM217 LM217K LM217TLM317D2T LM317 LM317K LM317T LM317PLM317电气参数：LM317如何应用计算图3决定LM317输出电压的是电阻R1,R2的比值,假设R2是一个固定电阻.因为输出端的电位高,电流经R1, R2流入接地点. LM317的控制端消耗非常少的电流,可忽略不计.所以, 控制端的电位是I x R2,又因为L M317 控制端, 输出端接脚间的电位差为1.25 V,所以O ut(输出）的电压是:接下来,计算I: out与adj接脚间的电位差为1.25 V,电阻R1.电流I是: 1.25/R1。

深圳市明烽威电子有限公司HCPL-4506-300E AVAGO HCPL-0600-500E AVAGOHCPL-4506-500E AVAGO HEDS-9701#C54AVAGOHCPL-4534-000E AVAGO TLC04CP TIHCPL-4534-300E AVAGO X9313WSZ-3T1INTERSILHCPL-4534-500E AVAGO TMS320LF2402APGA TIHCPL-4562-000E AVAGO TMS320LF2406APZA TIHCPL-4562-300E AVAGO AD9910BSVZ ADIHCPL-4562-500E AVAGO AD9957BSVZ ADIHCPL-4661-000E AVAGO TLV320AIC33IRGZ TIHCPL-4661-300E AVAGO TLV320AIC33IZQER TIHCPL-4661-500E AVAGO TPS54616PWPR TIHCPL-4731-000E AVAGO OPA551PA TIHCPL-4731-300E AVAGO DS1813R-15+DALLASHCPL-4731-500E AVAGO TPS7333QDR TIHCPL-7510-000E AVAGO OPA277UA TIHCPL-7510-300E AVAGO LM1877MX-9NSHCPL-7510-500E AVAGO ISO7221BDR TIHCPL-7520-000E AVAGO TL16C550CIPTR TIHCPL-7520-300E AVAGO MAX9324EUP+MAXIMHCPL-7520-500E AVAGO MAX1706EEE-T MAXIMHCPL-7560-000E AVAGO TPS75733KTTR TIHCPL-7560-300E AVAGO LM2674MX-ADJ NSHCPL-7560-500E AVAGO ADS8321EB TIHCPL-7611-000E AVAGO ADS8320EB TIHCPL-7611-300E AVAGO W29C040T-90B WINBONDHCPL-7611-500E AVAGO ISO124U TIHCPL-7710-000E AVAGO FM25L04B-GTR RAMTRONHCPL-7710-300E AVAGO TLE2084CN TIHCPL-7710-500E AVAGO TL317CDR TIHCPL-7720-000E AVAGO MAX354CPE+MAXIMHCPL-7720-300E AVAGO MAX354EPE+MAXIMHCPL-7720-500E AVAGO DEI0429-WMB DEIHCPL-7721-000E AVAGO AT91SAM7SE512-AU atmelHCPL-7721-300E AVAGO EL1881CSZ-T7INTERSILHCPL-7721-500E AVAGO SN74ACT2440FNR TIHCPL-7723-000E AVAGO MT4LC8M8C2P-5MICRONHCPL-7723-300E AVAGOHCPL-7800-000E AVAGOHCPL-7800-300E AVAGOHCPL-7800-500E AVAGOHCPL-7800A-000E AVAGOHCPL-7800A-300E AVAGOHCPL-7800A-500E AVAGOHCPL-7840-000E AVAGOHCPL-7840-300E AVAGOHCPL-7840-500E AVAGOHCPL786J-000E AVAGO HCPL-786J-000E AVAGO HCPL786J-300E AVAGO HCPL-786J-300E AVAGO HCPL786J-500E AVAGO HCPL-786J-500E AVAGO HCPL788J-000E AVAGO HCPL-788J-000E AVAGO HCPL788J-300E AVAGO HCPL-788J-300E AVAGO HCPL788J-500E AVAGO HCPL-788J-500EHCPL-817-000EHCPL-817-00AEHCPL-817-00BEHCPL-817-00CEHCPL-817-00DEHCPL-817-00LEHCPL-817-060EHCPL-817-06AEHCPL-817-06BEHCPL-817-06CEHCPL-817-06DEHCPL-817-06LEHCPL-817-300EHCPL-817-30AEHCPL-817-30BEHCPL-817-30CEHCPL-817-30DEHCPL-817-30LEHCPL-817-360EHCPL-817-36AEHCPL-817-36BEHCPL-817-36CEHCPL-817-36DEHCPL-817-36LEHCPL-817-500EHCPL-817-50AEHCPL-817-50BEHCPL-817-50CEHCPL-817-50DEHCPL-817-50LEHCPL-817-560EHCPL-817-56AEHCPL-817-56BEHCPL-817-56CEHCPL-817-56DEHCPL-817-56LEHCPL-9000-000E AVAGO DRV101FKTWT TIHCPL-9000-300E AVAGO DRV101F TIHCPL-9000-500E AVAGO UCC5638FQPR TIHCPL-902J-000E AVAGO TLV320AIC3204IRHBT TIHCPL-902J-300E AVAGO TLV320AIC3204IRHBR TIHCPL-902J-500E AVAGO TLV5625CDR TIHCPL-J312-000E AVAGO TLV5625IDR TIHCPL-J312-300E AVAGO TLV320AIC3104IRHBT TIHCPL-J312-500E AVAGO TLV320AIC3104IRHBR TIHCPL-J456-000E AVAGO AT45DB041D-SU ATMEL HCPL-J456-300E AVAGO MAX6657MSA+T MAXIM HCPL-J456-500E AVAGO HCPL-J454-000E AVAGO HCPL-M453-000E AVAGO HCPL-J454-300E AVAGO HCPL-M453-300E AVAGO HCPL-J454-400E AVAGO HCPL-M453-500E AVAGO HCPL-J454-500E AVAGO HCPL-M454-000E AVAGO HCPL-J454-600E AVAGO HCPL-M454-300E AVAGO TC7660IJA MICROCHIP HCPL-M454-500E AVAGO TC7660MJA MICROCHIP HCPL-M456-000E AVAGO ADT7460ARQZ ADIHCPL-M456-300E AVAGO ADSP-21065LKCA264ADIHCPL-M456-500E AVAGO ADSP-21065LKCAZ264ADI HCPL-M600-000E AVAGO AD7859ASZ ADI HCPL-M600-300E AVAGO MJD45H11G ONHCPL-M600-500E AVAGO TPD3E001DRLR TIHCPL-M601-000E AVAGO XTR116U TIHCPL-M601-300E AVAGO DS1233-5+DALLAS HCPL-M601-500E AVAGO TRU050GALGA32.0000/16.00Vectron HCPL-M611-000E AVAGO TRU050GACCA28.7040/14.35Vectron HCPL-M611-300E AVAGO AD9516-3BCPZ ADI HCPL-M611-500E AVAGO REF3125AIDBZT TIHCPL-M700-000E AVAGO REF3125AIDBZR TIHCPL-M700-300E AVAGO AD8592ARMZ ADI HCPL-M700-500E AVAGO QCPL-034H-500E AVAGOHD6413079F18HIT AD9865BCPZ ADI HDMP1636A AVAGO QCPL-312H-500E AVAGO HDMP-1636A AVAGO M74VHC1G135DFT1G ONHDMP-1637A AVAGO HSMD-A100-J00J1AVAGO HDMP1638AVAGO LT1587CT LTHDMP-1638AVAGO AD827JRZ-16ADI HEDS9710-R50AVAGO HSMP-389F-BLKG AVAGO HEDS-9710-R50AVAGO HSMP-389F-TR1G AVAGO HEL22MICREL HSMP-389F-TR2G AVAGO HEL23MICREL XC3064A-7PC84C XILINX HFBR-1414Z AVAGO XC3064A-7PC84I XILINX HFBR-1414TZ AVAGO Si7703EDN-T1-E3VISHAY HFBR-1521Z AVAGO Si7703EDN-T1-GE3VISHAYT-1521Z AVAGO Si7703EDN-T1-GE3ADIT-1521ETZ AVAGO AD605ARZ ADIHFBR-1521ETZ AVAGO MACH110-15JC AMDT-1522Z AVAGO MACH210-20JC AMDT-1522ETZ AVAGO LTC4213IDDB LINEAR HFBR-1522ETZ AVAGO DS1233-15+DALLAS HFBR1522Z AVAGO LTC3412EFE LINEAR HFBR-1522Z AVAGO MAX513ESD+T MAXIM HFBR1523Z AVAGO MAX3681EAG+MAXIM HFBR-1523Z AVAGO ICS1893CKILF IDT HFBR1528Z AVAGO TMS32C6416DGLZA5E0TI HFBR-1528Z AVAGO TMS32C6416EGLZ5E0TI HFBR-1531Z AVAGO TMS32C6416EGLZ6E3TI HFBR-1531ETZ AVAGO TMS32C6416EGLZ7E3TI HFBR-2531ETZ AVAGO TMS32C6416EGLZA5E0TI 1531ETZ AVAGO TMS32C6416EGLZA6E3TI 2531ETZ AVAGO AD829JRZ ADI HFBR1532Z AVAGO MAX14830ETM+MAXIM HFBR-1532Z AVAGO MX69GL128EAXGW-90G MXIC HFBR-1532ETZ AVAGO AD7811YRUZ ADI HFBR1533Z AVAGO TPS76318DBVR TI HFBR-1533Z AVAGO ADMP421ACEZ ADI HFBR-2412TZHFBR-2412ZHFBR2416TZHFBR-2416TZHFBR-2521Z AVAGO LT1304CS8Linear R-2521Z AVAGO MAX16801BEUA+T maxim R-2521ETZ AVAGO ACPL-M61L-500E AVAGO HFBR-2521ETZ AVAGO DS26503LN+DALLAS HFBR-2522Z AVAGO MAX9205EAI+T MAXIM R-2522Z AVAGO TMP105YZCT TIR-2522ETZ AVAGO TMP105YZCR TI HFBR-2522ETZ AVAGO AD5821BCBZ ADI HFBR-2523Z AVAGO PM5347-RI PMC HFBR-2528Z AVAGO PM73121-RI PMC HFBR-2531Z AVAGO TPA4411RTJT TI HFBR-2532Z AVAGO TPA4411RTJR TI HFBR-2532ETZ AVAGO LTC1438CG-ADJ Linear HFBR-2533Z AVAGO LTC1438IG-ADJ Linear HFBR-4501Z AVAGO DS1318E+DALLAS HFBR-4503Z AVAGO TMS320DM643AGDK5TI HFBR-4506Z AVAGO ACPL-M75L-000E AVAGO HFBR-4511Z AVAGO ACPL-M75L-060E AVAGO HFBR-4513Z AVAGO ACPL-M75L-500E AVAGO HFBR-4516Z AVAGO ACPL-M75L-560E AVAGO HFBR-4525Z AVAGO ACPL-T350-000E AVAGO HFBR-4526Z AVAGO ACPL-T350-060E AVAGO HFBR-4531Z AVAGO ACPL-T350-300E AVAGO HFBR-4532Z AVAGO ACPL-T350-360E AVAGOHFBR-4533Z AVAGO ACPL-T350-500E AVAGO HFBR-4535Z AVAGO ACPL-T350-560E AVAGO HFBR-4593Z AVAGO ADXRS620BBGZ ADI HFBR-4597Z AVAGO LT1521CS8Linear HFBR-EUD100Z AVAGO LT1521CS8-3.3Linear HFBR-EUD500Z AVAGO LT1521IS8Linear HFBR-EUS100Z AVAGO LT1521IS8-3.3Linear HFBR-EUS500Z AVAGO MAX6835VXSD3+T MAXIM HFBR-RUD100Z AVAGO AD9059BRSZ ADI HFBR-RUD500Z AVAGO HFBR-4515Z AVAGO HFBR-RUS100Z AVAGO HFBR-57E0PZ AVAGO HFBR-RUS500Z AVAGO HFCT-53D5EMZ AVAGO HG88510MITEL HFCT-5611AVAGOHI1-508-5HAR LT1242CS8Linear HI1-509-5HAR LT1242IS8Linear HM628512ALFP-5日立LT1140ACSW LinearHM628512BLFP-5日立AFBR-2419TZ AVAGO HS1101HUMIREL AD7156BCPZ ADIHS6118MACONICS ADP151ACBZ-2.8ADI HSDL-3201#021AVAGO DS1805Z-010+MAXIM HSDL-3201#001AVAGO TLP285-4GB TOSHIBA HSDL-3209-021AVAGO AD421BRZ ADI HSDL-7001#100AVAGO OPA2336PA TI HSDL-7002AVAGO ADUC812BSZ ADI HSMP-3814-BLKG AVAGO STPS6045CW ST HSMP-3814-TR1G AVAGO SG-3030JF EPSON HSMP-3814-TR2G AVAGO MPC8313VRAFFB FREESCAL HSMP-3822-BLKG AVAGO MAX1617AMEE+T maxim HSMP-3822-TR1G AVAGO MCP809M3X-4.63NS HSMP-3822-TR2G AVAGO MCP809M3X-4.38NS HSMP-3823-BLKG AVAGO MCP809M3X-4.00NS HSMP-3823-TR1G AVAGO MCP809M3X-3.08NS HSMP-3823-TR2G AVAGO MCP809M3X-2.93NS HSMP-3824-BLKG AVAGO MCP809M3X-2.63NS HSMP-3824-TR1G AVAGO MCP810M3X-4.63NS HSMP-3824-TR2G AVAGO MCP810M3X-4.38NS HSMP-3832-BLKG AVAGO MCP810M3X-4.00NS HSMP-3832-TR1G AVAGO MCP810M3X-3.08NS HSMP-3832-TR2G AVAGO MCP810M3X-2.93NS HSMP-3860-BLKG AVAGO MCP810M3X-2.63NS HSMP-3860-TR1G AVAGO LT1317BCS8Linear HSMP-3860-TR2G AVAGO LT1317BIS8Linear HSMP-3862-BLKG AVAGO LTC1757A-1EMS8Linear HSMP-3862-TR1G AVAGO ACPL-K342-000E AVAGO HSMP-3862-TR2G AVAGO ACPL-K342-500E AVAGO HSMP-3880-BLKG AVAGO AFBR-57M5APZ AVAGO HSMP-3880-TR1G AVAGO CY7C144AV-25AIT CY HSMP-3880-TR2G AVAGO CY7C144AV-25ACT CYHSMP-3892-BLKG AVAGO CY7C144AV-25AXIT CY HSMP-3892-TR1G AVAGO CY7C144AV-25AXCT CY HSMP-3892-TR2G AVAGO ABA-54563-TR1G AVAGO HSMP-389L-BLKG AVAGO ABA-54563-TR2G AVAGO HSMP-389L-TR1G AVAGO ABA-54563-BLKG AVAGO HSMP-389L-TR2G AVAGO LT1138ACG Linear HSMS-2812-BLKG AVAGO LT1138AIG Linear HSMS-2812-TR1G AVAGO ISL8120IRZ INTERSIL HSMS-2812-TR2G AVAGO ISL8120CRZ INTERSIL HSMS-2817-BLKG AVAGO LTC1421IG-2.5Linear HSMS-2817-TR1G AVAGO LTC1421CG-2.5Linear HSMS-2817-TR2G AVAGO MSC1212Y5PAGT TI HSMS-282K-BLKG AVAGO MSC1212Y5PAGR TI HSMS-282K-TR1G AVAGO TPS7330QDR TI HSMS-282K-TR2G AVAGO ADP3110KRZ ADI HSMS-2850-BLKG AVAGO MAX3263CAG MAXIM HSMS-2850-TR1G AVAGO MAX1729EUB MAXIM HSMS-2850-TR2G AVAGO MAX1651CSA MAXIM HSMS-8202-BLKG AVAGO AD876JR ADI HSMS-8202-TR1G AVAGO MAX1701EEE MAXIM HSMS-8202-TR2G AVAGO Si4201-BMR silicon HT2012-PL SMAR DS12C887+DALLAS HY62256ALT1-70HY LM236DR-2.5TIHY628100BLLG-70HY DS1722U DALLAS HY628100BLLG-70I HY LM7372MRX NSHY628400ALLG-55HY MAX490ESA+T MAXIM HY628400ALLG-70HY HSMS-2822-TR1G AVAGO HY62WT08081E-DG70C HY HSMP-389C-TR1G AVAGO HY62WT08081E-DG70I HY HSMP-389C-BLKG AVAGO ICL232IPE HAR HSMP-389C-TR2G AVAGO ICS8432DY-101ICS MC33375D-3.3R2G ONICS85322AM ICS AFBR-1529Z AVAGO ICS9112M-16ICS AFBR-2529Z AVAGO IDT75K62134S200BB IDT AFBR-1629Z AVAGO ILX139K SONY HSMS-2828-TR1G AVAGO IMP560ESA IMP TPS7101QDR TIIMP809JEUR-T IMP AFBR-57R5APZ AVAGO IMP809LEUR-T IMP UC3875DWPTR TIIMP809MEUR-T IMP ASSR-1510-503E AVAGO IMP809REUR-T IMP ASSR-1510-003E AVAGO IMP809SEUR-T IMP CY7B9514V-AC CYIMP809TEUR-T IMP MAX4450EXK+T MAXIM IMP810JEUR-T IMP SN75976A1DLR TIIMP810LEUR-T IMP ADUC831BSZ ADIIMP810MEUR-T IMP LTC1348IG LINEAR IMP810REUR-T IMP MSA-2111-TR1G AVAGO IMP810SEUR-T IMP DS1621S+T DALLAS IMP810TEUR-T IMP MAX485EESA+T MAXIMIMP811JEUS-T IMP MAX9669ETI+T MAXIM IMP811LEUS-T IMP MSA-0711-TR1G AVAGO IMP811MEUS-T IMP ACPL-P480-500E AVAGO IMP811REUS-T IMP HSMS-2800-TR1G AVAGO IMP811SEUS-T IMP LTC1622IS8LINEAR IMP811TEUS-T IMP MAX2102CWI MAXIM ACPL-312T-500E AVAGO X24165S-2.7T1XICOR ACPL-H342-560E AVAGO X84129SI-2.5T1XICOR ACPL-H342-500E AVAGO HCNW4502-500E AVAGO ACPL-H342-060E AVAGO HCNW4502-300E AVAGO ACPL-H342-000E AVAGO AD811ARZ-16ADI ACPL-K63L-500E AVAGO TOCP155TOSHIBA ACPL-K63L-560E AVAGO TOCP200TOSHIBA ACPL-K63L-000E AVAGO HFBR-14E4Z AVAGO AFBR-5803AQZ AVAGO HFBR-24E2Z AVAGO ASSR-4128-502E AVAGO ALM-2412-TR1G AVAGO HSMH-C680AVAGO TLV320DAC23GQER TIWS1403-TR1AVAGO CY2509ZXC-1T CYLST2825-T-SC AGILENT ACPL-312T-300E AVAGO MAX853ESA+T MAXIM MAX3814CHJ+T MAXIM。

DescriptionThese non-diffused lamps are designed to produce a bright light source and smooth radiationpattern. A slight tint is added to the lens for easy color identification.This lamp has been designed with aHLMP-C115, HLMP-C117, HLMP-C123, HLMP-C215, HLMP-C223,HLMP-C315, HLMP-C323, HLMP-C415, HLMP-C423, HLMP-C515,HLMP-C523, HLMP-C615, HLMP-C623Features•Very high intensity •Exceptional uniformity •Microtint lens for color identification•Consistent viewability All colors: AlGaAs RedHigh Efficiency Red Yellow Orange GreenEmerald Green •15° and 25° family•Tape and reel options available •Binned for color and intensity Applications•Ideal for backlighting front panels*•Used for lighting switches •Adapted for indoor and outdoor signsAgilentT-13/4 Super Ultra-Bright LED LampsData Sheet20mil lead frame, enhanced flange, and tight meniscus controls, making it compatible with radial lead automated insertion equipment.Selection GuidePart Number Luminous Intensity Iv (mcd) Color2θ1/2[1]Standoff Leads HLMP-Min.Max.DH AS AlGaAs15No C115290.0–C115-O00xx290.0–C115-OP0xx290.01000.0Yes C117-OP0xx290.01000.025No C12390.2–C123-L00xx90.2–Red15No C215138.0–C215-M00xx138.0–C215-MN0xx138.0400.025No C22390.2–C223-L00xx90.2–C223-MN0xx138.0400.0 Yellow15No C315147.0–C315-L00xx147.0–C315-LM0xx147.0424.025No C32396.2–C323-K00xx96.2–C323-KL0xx96.2294.0 Orange15No C415138.0–C415-M00xx138.0–C415-M0D0xx138.0–C415-MN0xx138.0400.025No C42390.2–C423-L00xx90.2–C423-LM0xx90.2276.0 Green15No C515170.0–C515-L00xx170.0C515-LM0xx170.0490.025No C52369.8–C523-J00xx69.8–C523-KL0xx111.7340.0 Emerald Green15No C61517.0–C615-G00xx17.0–25No C623 6.7–C623-E00xx 6.7–Part Numbering SystemHLMP - C x xx - x x x xxMechanical Options00: Bulk01: Tape & Reel, Crimped Leads02: Tape & Reel, Straight LeadsB2: Right Angle Housing, Even LeadsUQ: Ammo Pack, Horizontal LeadsColor Bin Options0: Full Color Bin DistributionD: Color Bins 4 & 5 onlyMaximum Iv Bin Options0: Open (No Maximum Limit)Others: Please refer to the Iv Bin TableMinimum Iv Bin OptionsPlease refer to the Iv Bin TableViewing Angle & Standoffs Options15: 15 Degree, without Standoffs17: 15 Degree, with Standoffs23: 25 Degree, without StandoffsColor Options1. AS AlGaAs Red2. High Efficiency Red3. Yellow4. Orange5. Green6. Emerald GreenPackage OptionsC: T-1 3/4 (5 mm)Absolute Maximum Ratings at T A = 25°CHighHighDH AS Efficiency Performance AlGaAs Red and Green and ParameterRed Orange Yellow Emerald Green Units DC Forward Current [1]30302030mA Transient Forward Current [2]500500500500mA (10 µsec Pulse)Reverse Voltage (Ir = 100 µA)5555V LED Junction Temperature 110110110110°C Operating Temperature Range –20 to +100–55 to +100–20 to +100°C Storage Temperature Range –55 to +100°CWave Soldering Temperature 250°C for 3 seconds [1.59 mm (0.063 in.) from body]Lead Solder Dipping Temperature 260°C for 5 seconds[1.59 mm (0.063 in.) from body]Notes:1. See Figure 5 for maximum current derating vs. ambient temperature.2. The transient current is the maximum nonrecurring peak current the device can withstand without damaging the LED die and wire bond.Package DimensionsHLMP-Cx15 and HLMP-Cx23HLMP-Cx17(0.039)NOTES:1. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).2. LEADS ARE MILD STEEL, SOLDER DIPPED.3. AN EPOXY MENISCUS MAY EXTEND ABOUT 0.5 mm (0.020 in.) DOWN THE LEADS.± 0.20± 0.008)Electrical Characteristics at T A = 25°CForward Reverse Capacitance Speed of ResponseVoltage Breakdown C (pF)Thermalτs (ns)Vf (Volts)Vr (Volts)Vf = 0Resistance Time Constant@ If = 20 mA@ Ir = 100 µA f = 1 MHz RθJ-PIN e-t/τsPart Number Typ.Max.Min.Typ.(°C/W)Typ.HLMP-C115 1.8 2.253021030HLMP-C117HLMP-C123HLMP-C215 1.9 2.651121090HLMP-C223HLMP-C315 2.1 2.651521090HLMP-C323HLMP-C415 1.9 2.654210280HLMP-C423HLMP-C515 2.2 3.0518210260HLMP-C523HLMP-C615 2.2 3.0518210260HLMP-C623Optical Characteristics at T A = 25°CLuminous Color,ViewingIntensity Peak Dominant Angle LuminousIv (mcd)Wavelength Wavelength2θ1/2Efficacy@ 20 mA[1]λpeak (nm)λd[2] (nm)(Degrees)[3]ηvPart Number Min.Typ.Typ.Typ.Typ.(lm/w) HLMP-C1152906006456371180HLMP-C117HLMP-C1239020026HLMP-C215138300635626171459017023HLMP-C315146300583585175009617025HLMP-C415138300600602173809017023HLMP-C515170300568570205956917028HLMP-C61517455585602065662728Notes:1. The luminous intensity, Iv, is measured at the mechanical axis of the lamp package. The actual peak of the spatial radiation pattern may not bealigned with this axis.2. The dominant wavelength, λd, is derived from the CIE Chromaticity Diagram and represents the color of the device.3. 2θ1/2 is the off-axis angle where the luminous intensity is 1/2 the on-axis intensity.Figure 1. Relative intensity vs. wavelength.Figure 2. Forward current vs. forward voltage (non-resistor lamp).Figure 3. Relative luminous intensity vs. forward current.WAVELENGTH – nmR E L A T I V E I N T E N S I T Y1.00.50I F – F O R W A R DC U R R E N T – m AV F – FORWARD VOLTAGE – VI F – F O R W A R D C U R R E N T – m AV F – FORWARD VOLTAGE – VHIGH EFFICIENCY RED, ORANGE,YELLOW, AND HIGH PERFORMANCEGREEN, EMERALD GREENR E L A T I V E L U M I N O U S I N TE N S I T Y (N O R M A L I Z E D A T 20 m A )I F – DC FORWARD CURRENT – mA R E L A T I V E L U M I N O U S I N T E N S I T Y (N O R M A L I Z E D A T 20 m A )0I DC – DC CURRENT PER LED – mA10201.60.80.4515301.2250.20.61.01.4HER, ORANGE, YELLOW, AND HIGH PERFORMANCE GREEN, EMERALD GREENFigure 5. Maximum forward dc current vs. ambient temperature. Derating based on T j MAX = 110°C.Figure 4. Relative efficiency (luminous intensity per unit current) vs. peak current.Figure 6. Relative luminous intensity vs. angular displacement. 15 degree family.R E L A T I V E E F F I C I E N C Y (N O R M A L I Z E D A T 20 m A )0I PEAK – PEAK FORWARD CURRENT – mA0.60.8300201001.21.00.20.45020010DH As AlGaAs REDηP E A K – R E L A T I V E E F F I C I E N C Y (N O R M A L I Z E D A T 20 m A )I PEAK – PEAK FORWARD CURRENT – mAHER, ORANGE, YELLOW, HIGHPERFORMANCE GREEN, EMERALD GREENI F – F O R W A R D C U R R E NT – m AT A – AMBIENT TEMPERATURE – °C DH As AlGaAs REDI F – F O R W A R D C U R R E N T – m AT A – AMBIENT TEMPERATURE – °CHER, ORANGE, YELLOW, AND HIGH PERFORMANCE GREEN, EMERALD GREEN N O R M A L I Z E D L U M I N O U S I N T E N S I T Y10ANGULAR DISPLACEMENT – DEGREES0.80.60.50.70.2450.10.30.4403530252010515-5-10-15-20-25-30-35-40-450.9Figure 7. Relative luminous intensity vs. angular displacement. 25 degree family.Intensity Bin Limits Intensity Range (mcd)ColorBin Min.Max.L 101.5162.4M 162.4234.6N 234.6340.0O 340.0540.0P 540.0850.0Q 850.01200.0R 1200.01700.0Red/OrangeS 1700.02400.0T 2400.03400.0U 3400.04900.0V 4900.07100.0W 7100.010200.0X 10200.014800.0Y 14800.021400.0Z 21400.030900.0L 173.2250.0M 250.0360.0N 360.0510.0O 510.0800.0P 800.01250.0YellowQ 1250.01800.0R 1800.02900.0S 2900.04700.0T 4700.07200.0U 7200.011700.0V 11700.018000.0W18000.027000.0N O R M A L I Z E D L U M I N O U S I N T E N S I T Y10ANGULAR DISPLACEMENT – DEGREES0.80.60.50.70.2450.10.30.4403530252010515-5-10-15-20-25-30-35-40-450.9Intensity Bin Limits, continuedIntensity Range (mcd) Color Bin Min.Max.E7.612.0F12.019.1G19.130.7H30.749.1I49.178.5J78.5125.7K125.7201.1L201.1289.0 Green/M289.0417.0 Emerald Green N417.0680.0O680.01100.0P1100.01800.0Q1800.02700.0R2700.04300.0S4300.06800.0T6800.010800.0U10800.016000.0V16000.025000.0W25000.040000.0 Maximum tolerance for each bin limit is ± 18%.Color CategoriesLambda (nm)Color Category #Min.Max.6561.5564.55564.5567.5 Green4567.5570.53570.5573.52573.5576.51582.0584.53584.5587.0 Yellow2587.0589.54589.5592.05592.0593.01597.0599.52599.5602.03602.0604.5 Orange4604.5607.55607.5610.56610.5613.57613.5616.58616.5619.5 Tolerance for each bin limit is ± 0.5 nm.Mechanical Option MatrixMechanical Option Code Definition00Bulk Packaging, minimum increment 500 pcs/bag01Tape & Reel, crimped leads, minimum increment 1300 pcs/bag02Tape & Reel, straight leads, minimum increment 1300 pcs/bagB2Right Angle Housing, even leads, minimum increment 500 pcs/bagUQ Ammo Pack, horizontal leads, in 1K minimum incrementNote:All categories are established for classification of products. Products may not be available in all categories. Please contact your local Agilent representative for further clarification/information./semiconductorsFor product information and a complete list ofdistributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or(916) 788-6763Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6756 2394India, Australia, New Zealand: (+65) 6755 1939Japan: (+81 3) 3335-8152 (Domestic/Interna-tional), or 0120-61-1280 (Domestic Only)Korea: (+65) 6755 1989Singapore, Malaysia, Vietnam, Thailand,Philippines, Indonesia: (+65) 6755 2044Taiwan: (+65) 6755 1843Data subject to change.Copyright © 2004 Agilent Technologies, Inc.Obsoletes 5965-6165ENovember 11, 20045988-2149EN。

LED Light Bars Technical DataFeatures•Large Bright, Uniform Light Emitting Areas•Choice of Colors •Categorized for Light Output •Yellow and Green Categorized for Dominant Wavelength•Excellent ON-OFF Contrast •X-Y Stackable•Flush Mountable•Can be Used with Panel and Legend Mounts• Light Emitting Surface Suitable for Legend Attachment per Application Note 1012•HLCP-X100 Series Designed for Low Current Operation •Bicolor Devices Available Applications•Business MachineMessage Annunciators •Telecommunications Indicators•Front Panel Process Status Indicators•PC Board Identifiers•Bar Graphs DescriptionThe HLCP-X100 and HLMP-2XXXseries light bars are rectangularlight sources designed for avariety of applications where alarge bright source of light isrequired. These light bars areconfigured in single-in-line anddual-in-line packages that containeither single or segmented lightemitting areas. The AlGaAs RedHLCP-X100 series LEDs usedouble heterojunction AlGaAs ona GaAs substrate. The HERHLMP-2300/2600 and YellowHLMP-2400/2700 series LEDshave their p-n junctions diffusedinto a GaAsP epitaxial layer on aGaP substrate. The Green HLMP-2500/2800 series LEDs use aliquid phase GaP epitaxial layeron a GaP substrate. The bicolorHLMP-2900 series use acombination of HER/Yellow orHER/Green LEDs.HLCP-A100, -B100, -C100,-D100, -E100, -F100, -G100,-H100HLMP-2300, -2350, -2400,-2450, -2500, -2550, -2600,-2620, -2635, -2655, -2670,-2685, -2700, -2720, -2735,-2755, -2770, -2785, -2800,-2820, -2835, -2855, -2870,-2885, -2950, -2965Selection GuideLight Bar Part Number Corresponding Size ofPackage Panel and HLCP-HLMP-Light Emitting AreasOutlineLegend Mount Part No. HLMP-AlGaAs HER Yellow Green A1002300240025008.89 mm x 3.81 mm 1A 2599(.350 in. x .150 in.)B10023502450255019.05 mm x 3.81 mm 1B 2598(.750 in. x .150 in.)D1002600270028008.89 mm x 3.81 mm 2D 2898(.350 in. x .150 in.)E1002620272028208.89 mm x 3.81 mm 4E 2899(.350 in. x .150 in.)F100263527352835 3.81 mm x 19.05 mm 2F 2899(.150 in. x .750 in.)C1002655275528558.89 mm x 8.89 mm 1C 2898(.350 in. x .350 in.)G1002670277028708.89 mm x 8.89 mm 2G 2899(.350 in. x .350 in.)H1002685278528858.89 mm x 19.05 mm 1H 2899(.350 in. x .750 in.)295029508.89 mm x 8.89 mm Bicolor I 2898(.350 in. x .350 in.)296529658.89 mm x 8.89 mm BicolorI2898(.350 in. x .350 in.)Number of Light Emitting AreasPart Numbering SystemHLCP- xx xx-xx x xxHLMP-xx xx-xx x xxMechanical Options[1]00: No mechanical optionColor Bin Options[1,2]0: No color bin limitationB: Color bins 2 & 3 (applicable for yellow devices only)C: Color bins 3 & 4 only (applicable for green devices only)Maximum Intensity Bin[1,2]0: No maximum intensity bin limitationMinimum Intensity Bin[1,2]0: No minimum intensity bin limitationDevice Specific Configuration[1]Refer to respective data sheetColor[1]x1: AlGaAs Red (applicable for HLCP-x100 only)23: High Efficiency Red24: Yellow25: Green26: High Efficiency Red27: Yellow28: Green29: Bicolor (High Efficiency Red/Yellow) OR (High Efficiency Red/Green) Notes:1. For codes not listed in the figure above, please refer to the respective data sheet or contact your nearest Agilent representativefor details.2. Bin options refer to shippable bins for a part-number. Color and Intensity Bins are typically restricted to 1 bin per tube(exceptions may apply). Please refer to respective data sheet for specific bin limit information.Package DimensionsNOTES:1. DIMENSIONS IN MILLIMETRES (INCHES). TOLERANCES ±0.25 mm (±0.010 IN.) UNLESS OTHERWISE INDICATED.2. FOR YELLOW AND GREEN DEVICES ONLY.Internal Circuit DiagramsIAbsolute Maximum RatingsHER Yellow GreenAlGaAs Red HLMP-2300/HLMP-2400/HLMP-2500/ ParameterHLCP-X1002600/29XX2700/29502800/2965Series Series Series Series Average Power Dissipated per LED Chip37 mW[1]135 mW[2]85 mW[3]135 mW[2] Peak Forward Current per LED Chip45 mA[4]90 mA[5]60 mA[5]90 mA[5] Average Forward Current per LED Chip15 mA25 mA20 mA25 mADC Forward Current per LED Chip15 mA[1]30 mA[2]25 mA[3]30 mA[2] Reverse Voltage per LED Chip 5 V 6 V[6]Operating Temperature Range–20°C to +100°C[7]–40°C to +85°C–20°C to +85°C Storage Temperature Range –40°C to +85°CWave Soldering Temperature250°C for 3 seconds1.6 mm (1/16 inch) below BodyNotes:1.Derate above 87°C at 1.7 mW/°C per LED chip. For DC operation, derate above 91°C at 0.8 mA/°C.2.Derate above 25°C at 1.8 mW/°C per LED chip. For DC operation, derate above 50°C at 0.5 mA/°C.3.Derate above 50°C at 1.8 mW/°C per LED chip. For DC operation, derate above 60°C at 0.5 mA/°C.4.See Figure 1 to establish pulsed operation. Maximum pulse width is 1.5 mS.5.See Figure 6 to establish pulsed operation. Maximum pulse width is 2 mS.6.Does not apply to bicolor parts.7.For operation below –20°C, contact your local Agilent sales representative.Electrical/Optical Characteristics at T A = 25°CAlGaAs Red HLCP-X100 SeriesParameter HLCP-Symbol Min.Typ.Max.Units Test ConditionsA100/D100/E100I V37.5mcd I F = 3 mA Luminous Intensityper Lighting Emitting B100/C100/F100/G100615mcdArea[1]H1001230mcdPeak WavelengthλPEAK645nmDominant Wavelength[2]λd637nmForward Voltage per LED V F 1.8 2.2V I F = 20 mA Reverse Breakdown Voltage per LED V R515V I R = 100 µA Thermal Resistance LED Junction-to-Pin RθJ-PIN250°C/W/LEDParameter HLMP-Symbol Min.Typ.Max.Units Test Conditions2400/2700/2720IV 620mcd IF= 20 mALuminous Intensityper Lighting Emitting2450/2735/2755/2770/2950[3]1338mcd Area[1]27852670mcdPeak WavelengthλPEAK583nmDominant Wavelength[2]λd585nmForward Voltage per LED VF 2.1 2.6V IF= 20 mAReverse Breakdown Voltage per LED[5]VR 615V IR= 100 µAThermal Resistance LED Junction-to-Pin RθJ-PIN 150°C/W/LEDHigh Efficiency Red HLMP-2300/2600/2900 SeriesParameter HLMP-Symbol Min.Typ.Max.Units Test Conditions2300/2600/2620IV 623mcd IF= 20 mALuminous Intensityper Lighting Emitting2350/2635/2655/2670/2950[3]1345mcd Area[1]2965[4]1945mcd26852280mcdPeak WavelengthλPEAK635nmDominant Wavelength[2]λd626nmForward Voltage per LED VF 2.0 2.6V IF= 20 mAReverse Breakdown Voltage per LED[5]VR 615V IR= 100 µAThermal Resistance LED Junction-to-Pin RθJ-PIN 150°C/W/LEDYellow HLMP-2400/2700/2950 SeriesHigh Performance Green HLMP-2500/2800/2965 SeriesParameter HLMP-Symbol Min.Typ.Max.Units Test Conditions2500/2800/2820IV 525mcd IF= 20 mALuminous Intensityper Lighting Emitting2550/2835/2855/28701150mcd Area[1]2965[4]2550mcd288522100mcdPeak WavelengthλPEAK565nmDominant Wavelength[2]λd572nmForward Voltage per LED VF 2.2 2.6V IF= 20 mAReverse Breakdown Voltage per LED[5]VR 615V IR= 100 µAThermal Resistance LED Junction-to-Pin RθJ-PIN 150°C/W/LEDNotes:1.These devices are categorized for luminous intensity. The intensity category is designated by a letter code on the side of the package.2.The dominant wavelength, λd , is derived from the CIE chromaticity diagram and is the single wavelength which defines the color of thedevice. Yellow and Green devices are categorized for dominant wavelength with the color bin designated by a number code on the side of the package.3.This is an HER/Yellow bicolor light bar. HER electrical/optical characteristics are shown in the HER table. Yellow electrical/opticalcharacteristics are shown in the Yellow table.4.This is an HER/Green bicolor light bar. HER electrical/optical characteristics are shown in the HER table. Green electrical/opticalcharacteristics are shown in the Green table.5.Does not apply to HLMP-2950 or HLMP-2965.Figure 1. Maximum Allowable Peak Current vs. Pulse Duration.Figure 4. Forward Current vs. Forward Voltage.Figure 5. Relative Luminous Intensity vs. DC Forward Current.AlGaAs RedFigure 2. Maximum Allowed DC Current per LED vs.Ambient Temperature, T J MAX = 110°C.Figure 3. Relative Efficiency (Luminous Intensity per UnitCurrent) vs. Peak LED Current.For a detailed explanation on the use of data sheet information and recommended soldering procedures,see Application Notes 1005, 1027, and 1031.HER, Yellow, GreenFigure 9. Forward Current vs. Forward Voltage Characteristics.Figure 10. Relative Luminous Intensity vs. DC ForwardCurrent.Figure 6. Maximum Allowed Peak Current vs. Pulse Duration.Figure 7. Maximum Allowable DC Current per LED vs.Ambient Temperature, T J MAX = 100°C.Figure 8. Relative Efficiency (Luminous Intensity per Unit Current) vs. Peak LED Current.Intensity Bin Limits (mcd)HLMP-2300/2600/2620 Annunciators (.2 x .4 HER/AlGaAs), HLCP-A100/D100/E100IV Bin Category Min.Max.A 3.00 5.60B 4.508.20C 6.8012.10D10.1018.50E15.3027.80F22.8045.50G36.9073.80Notes:1. Minimum category A for Red L/C AlGaAs (-A100/-D100/-E100).2. Minimum category C for HER (-2300/-2600/-2620).HLMP-2350/2635/2655/2670 Annunciators (.2 x .8 HER/AlGaAs), HLCP-B100/C100/F100/G100 (.4 x .4 HER/AlGaAs)IV Bin Category Min.Max.A 5.4010.90B9.0016.00C13.1024.00D19.7036.10E29.6054.20F44.9088.80G71.90143.80Notes:1. Minimum category A for Red L/C AlGaAs (-B100/-C100/-F100/-G100).2. Minimum category C for HER (-2350/-2635/-2670).HLMP-2685/HLCP-H100 Annunciators (.4 x .8 HER/AlGaAs) IV Bin Category Min.Max.A10.8022.00B18.0027.10C22.0040.80D33.3061.10E50.0091.80F75.10150.00G121.70243.40Notes:1. Minimum category A for Red L/C AlGaAs (-H100).2. Minimum category C for HER (-2685).HLMP-2400/2700/2720 Annunciators (.2 x .4 Yellow)IV Bin Category Min.Max.C 6.1011.20D9.2016.80E13.8025.30F20.7041.40G33.6067.20HLMP-2450/2735/2755/2770 Annunciators (.2 x .8 Yellow & .4 x .4 Yellow) IV Bin Category Min.Max.C13.0022.00D18.0033.00E27.0050.00F40.5081.00G65.60131.20HLMP-2785 Annunciators (.4 x .8 Yellow)IV Bin Category Min.Max.C26.0044.40D36.0066.00E54.0099.00F81.00162.00G131.40262.80HLMP-2500/2800/2820 Annunciators (.2 x .4 Yellow)IV Bin Category Min.Max.C 5.6010.20D8.4015.30E12.6023.10F18.9037.80G30.6061.20H49.5097.90I80.10158.40HLMP-2550/2835/2855/2870 Annunciators (.2 x .8/.4 x .4 Green) IV Bin Category Min.Max.C11.3020.60D17.0031.00E25.4046.50F38.1076.20G61.60123.20H99.81197.67I161.73320.21HLMP-2885 Annunciators (.4 x .8 Green)IV Bin Category Min.Max.C22.2040.80D33.4061.20E50.1091.90F75.10150.30G121.10242.20H196.10383.50I313.70613.60HLMP-2950 Bi-Color Annunciators (.4 x .4 HER/Yellow) IV Bin Category Min.Max.Red Iv CategoriesC11.3020.60D17.0031.00E25.4046.50F38.1076.20G61.60123.20Yellow Iv CategoriesC13.0022.00D18.0033.00E27.0050.00F40.5081.00G65.60131.20HLMP-2965 Bi-Color Annunciators (.4 x .4/.2 x .8 HER/Green) IV Bin Category Min.Max.Red Iv CategoriesD19.7036.10E29.6054.20F44.9088.80G71.90143.80Green Iv CategoriesB7.5013.90C11.3020.60D17.0031.00E25.4046.50F38.1076.20G61.60123.20H100.00200.00Notes:1. Minimum category D for LPE Green (-2965).2. In green mode, the devices are to be color binned into standard color bins, perTable 2. (-2685).Color CategoriesNote:All categories are established for classification of products. Products may not be available in all categories. Please contact your local Agilent representatives for further clarification/information.I AVG I v TIME AVG =I TESTwhere:I TEST =3 mA for AlGaAs Red(HLMP-X000 series)20 mA for HER,Yellow and Green (HLMP-2XXX series)Example:For HLMP-2735 series ηI PEAK = 1.18 at I PEAK = 48 mA12 mA I v TIME AVG =20 mA= 25 mcd[][]ElectricalThese light bars are composed of two, four, or eight light emitting diodes, with the light from each LED optically scattered to form an evenly illuminated light emitting surface.The anode and cathode of each LED is brought out by separate pins. This universal pinoutarrangement allows the LEDs to be connected in three possible configurations: parallel, series, or series parallel. The typical forward voltage values can be scaled from Figures 4 and 9.These values should be used to calculate the current limiting resistor value and typical power consumption. Expected maximum V F values for driver circuit design and maximum power dissipation,may be calculated using the following V F MAX models:AlGaAs Red HLCP-X100 series V F MAX = 1.8 V + I Peak (20 Ω)For: I Peak ≤ 20 mAV F MAX = 2.0 V + I Peak (10 Ω)For: 20 mA ≤ I Peak ≤ 45 mA HER (HLMP-2300/2600/2900),Yellow (HLMP-2400/2700/2900)and Green (HLMP-2500/2800/2900) seriesV F MAX = 1.6 + I Peak (50 Ω)For: 5 mA ≤ I Peak ≤ 20 mA V F MAX = 1.8 + I Peak (40 Ω)For: I Peak ≥ 20 mAThe maximum power dissipation can be calculated for any pulsed or DC drive condition. For DC operation, the maximum powerdissipation is the product of the maximum forward voltage and the maximum forward current. For pulsed operation, the maximum power dissipation is the product of the maximum forward voltage at the peak forward current times the maximum average forward current. Maximum allowable power dissipation for any given ambient temperature and thermal resistance (R θJ-A ) can be deter-mined by using Figure 2 or 7. The solid line in Figure 2 or 7 (R θJ-A of 600/538 C/W) represents a typical thermal resistance of a device socketed in a printed circuitboard. The dashed lines represent achievable thermal resistances that can be obtained through improved thermal design. Once the maximum allowable power dissipation is determined, the maximum pulsed or DC forward current can be calculated.OpticalSize of Light Surface Area Emitting Area Sq. Metres Sq. Feet 8.89 mm x 8.89 mm 67.74 x 10–6729.16 x 10–68.89 mm x 3.81 mm 33.87 x 10–6364.58 x 10–68.89 mm x 19.05 mm 135.48 x 10–61458.32 x 10–63.81 mm x 19.05 mm72.85 x 10–6781.25 x 10–6The radiation pattern for these light bar devices is approximately Lambertian. The luminoussterance may be calculated using one of the two following formulas:I v (cd)L v (cd/m 2) =A (m 2)πI v (cd)L v (footlamberts) =A (ft 2)Refresh rates of 1 kHz or faster provide the most efficientoperation resulting in the maxi-mum possible time average luminous intensity.The time average luminousintensity may be calculated using the relative efficiency character-istic of Figure 3 or 8, ηI PEAK , and adjusted for operating ambient temperature. The time average luminous intensity at T A = 25°C is calculated as follows:(ηI PEAK ) (I v Data Sheet)(1.18) (35 mcd)The time average luminous intensity may be adjusted for operating ambient temperature by the following exponential equation:I v (T A) = I V (25°C)e[K (T –25°C)]Color KAlGaAs Red–0.0095/°CHER–0.0131/°C Yellow–0.0112/°C Green–0.0104/°CExample:I v (80°C) = (25 mcd)e[-0.0112 (80-25)] = 14 mcd.MechanicalThese light bar devices may beoperated in ambient temperaturesabove +60°C without deratingwhen installed in a PC boardconfiguration that provides athermal resistance pin to ambientvalue less than 280°C/W/LED. SeeFigure 2 or 7 to determine themaximum allowed thermalresistance for the PC board,RθPC-A, which will permitnonderated operation in a givenambient temperature.To optimize device opticalperformance, specially developedplastics are used which restrictthe solvents that may be used forcleaning. It is recommended thatonly mixtures of Freon (F113)and alcohol be used for vaporcleaning processes, with animmersion time in the vapors ofless than two (2) minutesmaximum. Some suggested vaporcleaning solvents are Freon TE,Genesolv DES, Arklone A or K. A60°C (140°F) water cleaningprocess may also be used, whichincludes a neutralizer rinse (3%ammonia solution or equivalent),a surfactant rinse (1% detergentsolution or equivalent), a hotwater rinse and a thorough airdry. Room temperature cleaningmay be accomplished with FreonT-E35 or T-P35, Ethanol,Isopropanol or water with a milddetergent.For further information onsoldering LEDs please refer toApplication Note 1027.A/semiconductorsFor product information and a complete list ofdistributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or(916) 788-6763Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6756 2394India, Australia, New Zealand: (+65) 6755 1939Japan: (+81 3) 3335-8152 (Domestic/Interna-tional), or 0120-61-1280 (Domestic Only)Korea: (+65) 6755 1989Singapore, Malaysia, Vietnam, Thailand,Philippines, Indonesia: (+65) 6755 2044Taiwan: (+65) 6755 1843Data subject to change.Copyright © 2004 Agilent Technologies, Inc.Obsoletes 5962-7197EJuly 8, 20045988-2221EN。