全中文芯片资料TSS721A仪表总线收发器

±2G/±4G/±8G/±16G三轴微机械数字加速度计描述SC7A20是一款高精度12bit数字三轴加速度传感器芯片，内置功能更丰富，功耗更低，体积更小，测量更精确。

芯片通过I²C/SPI接口与MCU通信，加速度测量数据以中断方式或查询方式获取。

INT1和INT2中断管脚提供多种内部自动检测的中断信号，适应多种运动检测场合，中断源包括6D/4D方向检测中断信号、自由落体检测中断信号、睡眠和唤醒检测中断信号、单击和双击检测中断信号。

芯片内置高精度校准模块，对传感器的失调误差和增益误差进行精确补偿。

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

芯片内置自测试功能允许客户系统测试时检测系统功能，省去复杂的转台测试。

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

主要特点♦宽电压范围1.71V-3.6V♦ 1.8V兼容数字IO口♦低功耗模式下电源电流低至2µA♦±2G/±4G/±8G/±16G动态全量程范围♦12bit有效数据(HR)♦I²C/SPI数字输出接口♦6D/4D方向检测♦自由落体检测♦单击双击检测及运动检测♦可编程中断生成电路♦内嵌自测试功能♦内嵌FIFO♦10000g高G抗击能力应用♦手机平板♦室内导航♦图像旋转♦运动激活用户接口♦游戏产品规格分类内部框图INT1INT2CSSCL/SPCSDA/SDO/SDISDO/SA0极限参数=25°C)机械参数(VDD=2.5V, TA注意：电路2.5V出厂校准。

电路实际工作电压1.71V-3.6V=25°C)电气参数(VDD=2.5V, TAI²C控制接口参数(=2.5V, TA=25°C)I²C从设备时序图SPI串行外围接口参数(VDD =2.5V, TA=25°C)注：10MHZ时钟速率SPI 从设备时序图管脚排列图7（仰视图）X（俯视图）可检加速度方向管脚描述注：I=输入，O=输出，OC=集电极开路输出，P=被动外部器件，S=电源供电功能描述1详细特点SC7A20是一款极小体积、超低功耗、数字输出的LGA封装的3轴线性加速度计。

TSS721A将整个数据发送与接收功能集成于一体，其内部功能框图如图5.4所示。

芯片的外形封装如图5.5所示。

图5.6为各个管脚功能的简单说明。

该芯片具有以下主要功能：(1) 满足国际EN1434-3标准；(2) 具有动态电平识别的接收逻辑；(3) 通过电阻可调接收电流；(4) 无极性连接；(5) 防掉电功能；(6) 可提供3.3V稳压源；(7) 支持远程供电；(8) 半双工下通信速率可达9600波特率，支持UART协议；(9) 从机可由总线或后备电池供电；(10) 只在数据传输时总线有效。

图5.4 TSS721A内部功能框图图5.5 TSS721A外形封装图5.6TSS721A管脚功能说明5.3.4.2 TSS721A的工作原理(1) 从机接收电路：TSS721A在此模式下采用总线电压调制传输数据，而总线电流保持恒定。

总线电压U BUS=U MARK(标识值)是由从机管脚BUSL1和BUSL2之间的电压差定义的。

主从机间距离会影响该电压差。

为使接收与距离无关，将管脚SC上的动态参考电平引入电压比较器TC3，见图5.7。

连接在管脚SC上的电容C SC的充电电流I SCcharge和放电电流I SCdischarge不同，一般有如下关系：I SCdischarge= I SCcharge/40。

图5.7主机到从机的数据传输这个比例关系是独立于数据内容运行任意UART协议所必需的条件(例如，如果传输采用11位UART协议，当所传数据只有停止位为“1”，其它位都为“0"的情况)，必须有足够的时间来对电容C SC进行再充电。

电压比较器TC3检测来自主机的调制电压，并根据该电压U BUS=U SPACE(空值)或U MARK(标识值)来开关正端输出TX和反端输出TX1。

(2) 从机发送电路：TSS721A在此模式下使用总线电流调制传输数据，而总线电压保持恒定。

芯片内电流源电流I CS3调制总线电流，由主机检测调制电流。

TSS721A技术资料总结一，芯片简介TSS721A是一种用于仪表总线的收发器集成芯片，其内含的接口电路可以调节仪表总线结构中主从机的电平，可通过光耦等隔离器件与总线连接，通过数据收发器由总线供电。

芯片封装采用DIP16封装，将整个数据发送功能集成于一体，内部功能框图如图1所示，管脚功能介绍如下：图11，满足国际EN1434-3标准2，具有动态电平识别的接收电流3，通过限流电阻可调接收电流4，无极性连接5，放掉电功能6，可提供3.3.V稳压源7，支持远程供电，从机可由总线或电池供电8，半双工下可达9600 Baud rate9，支持UART协议，只在数据传输时总线有效二，管脚功能管脚号 管脚定义 功能1 BUSL2 仪表总线接入端2 VB 整流后总线电压差连接端3 STC 供电电容接入端4 RIDD 电流调节接入端5 PF 掉电信号输出端6 SC 采样电容连接端7 TXI 数据输出端8 TX 数据输出端9 BAT 逻辑电平调节端10 VS 总线或电池供电输出选择端11 VDD 稳压输入端12 RX 数据输出端13 RXI 数据输出端14 RIS 调制电流调节输入端15 GND 接地端16 BUSL1 仪表总线接入端三，数据传输模式MBUS传输原理1，主——>从此模式下采用电压调制传输数据，总线电流保持不变。

即主机发送的数据码流是一种电压脉冲序列，用+36V标识逻辑‘1’，用+24V标识逻辑‘0’。

在稳态时，线路将保持‘1’状态。

如图2所示：图2总线电压Vbus=MARK（标识值）是由从机BUSL1和BUSL2间压差定义的，连接在管脚SC上的电容Csc的充放电流是不同的，存在以下关系：ISCcharge =ISCdischarge/40这个比例关系是独立于数据内容运行任意UART协议所必须的条件（例如传输采用11位UART协议，当所有数据只有停止位是1.其他都是0），必须有足够的时间对电容Csc进行再充电，内部电压比较器TC3检测来自主机的调制电压，并根据电压VBUS=SPACE（空值）或MARK（标识值）来开关正端输出TX和反向端输出TXI，输出数据给从机。

ch7217a中文规格书
【原创版】
目录
1.介绍 ch7217a 中文规格书
2.ch7217a 的功能特点
3.ch7217a 的技术参数
4.ch7217a 的应用领域
5.结论
正文
ch7217a 中文规格书是一款详细的中文规格说明书，它包含了 ch7217a 的各种信息，如功能特点、技术参数和应用领域等。

ch7217a 的功能特点主要体现在以下几个方面：首先，它具有强大的数据处理能力，能够快速、准确地处理各种数据；其次，它具有良好的用户界面，方便用户进行各种操作；最后，它还具有可靠的安全性能，能够有效地保护用户的数据安全。

在技术参数方面，ch7217a 的表现也非常出色。

它采用了先进的技术，使得它的性能指标都达到了行业的领先水平。

例如，它的处理速度、存储容量、接口类型等都处于行业的前列。

ch7217a 的应用领域非常广泛，它主要应用于科学研究、工程设计、商业分析等各个领域。

凭借其强大的数据处理能力和良好的用户界面，ch7217a 能够为这些领域的用户提供高效的数据处理服务。

第1页共1页。

摘要SF6断路器微水在线监测仪以PIC16F877单片机作为处理器，来实现实时监测SF6气体的温度、湿度及压力，从而得知断路器的运行状态。

对由于SF6气体本身原因引起的绝缘故障做出有效应对，进而保证电网的运行安全。

本次设计的SF6断路器微水在线监测系统的基本原理为：将湿度、温度、压力传感器通过连接器件连接到SF6气室，测量气室内SF6气体的湿度、温度、压力。

所测模拟量送入PIC16F877单片机，通过A/D转换,数据分析，实施数据越限报警，并用LCD显示温度、压力以及湿度。

下位机与上位机的通讯遵循MODBUS通讯协议，生成标准通信数据包。

数据包通过M-BUS总线送入上位机，进行计算机实时监控。

关键字：PIC16F877单片机；M-BUS总线；软件编程；AbstractSF6 circuit breakers monitor online system uses the PIC16F877 microcontroller as a processor, to achieve real-time monitoring of SF6gas’s temp erature, humidity and pressure, and to kown the running state of circuit breakers so that people could effectively deal with the insulation fault caused by SF6 gas itself, and ensure the safty of the power supply system.In this design,the basic principles of SF6circuit breaker can be summarized as that the humidity sensor, temperature sensor and pressure sensor are connected to the SF6gas room by the jointer,which can survey the humidity, temperature, pressure of SF6 gas. the measured analog go through the A / D conversion, data analysis in the PIC16F877 microcontroller, to implement data overrun alarm and demonstrate temperature, pressure and humidity.The information transmission between slaves and the master generates a standard communication packets based on MODBUS protocol to achieve real-time control.Keyword:PIC16F877 microcontroller; M-BUS bus; software programming;目录摘要 (I)ABSTRACT (II)第一章绪论 (1)1.1选题背景 (1)1.2主要设计（研究）内容 (3)1.3系统主要技术指标 (3)1.4解决的关键问题 (3)第二章系统总体结构方案设计 (5)2.1系统总体结构及其功能 (5)2.2方案设计 (5)2.2.1方案一 (5)2.2.2方案二 (6)2.3方案论证 (7)2.4方案的确定 (7)第三章系统的硬件设计 (9)3.1单片机 (10)3.1.1 PIC16F877单片机特点 (10)3.1.2外围电路 (11)3.2温度传感器 (12)3.2.1温度传感器的选型 (12)3.2.2 温度传感器接口电路 (14)3.2.3 小结 (14)3.3湿度传感器 (14)3.3.1湿度传感器的选型 (15)3.3.2 接口电路 (16)3.3.3 小结 (17)3.4压力传感器 (18)3.4.1压力传感器的选型 (18)3.4.2 接口电路 (19)3.4.3 小结 (19)3.5键盘电路 (19)3.6报警电路 (20)3.7LCD显示模块 (20)3.7.1 LCD显示模块的选型 (21)3.7.2 接口电路 (21)3.7.3 小结 (21)3.8掉电保护模块 (22)3.8.1掉电保护的选型 (22)3.9M-BUS通讯模块 (22)3.9.1M-BUS总线介绍 (23)3.10通讯接口电路的设计 (24)3.10.1 TSS721A芯片介绍 (25)3.10.2 TSS721A芯片与单片机接口电路设计 (27)3.10.3小结 (29)3.11电源的设计 (29)3.11.1电源选择 (29)3.11.2 接线电路 (30)3.11.3电源的抗干扰技术 (31)3.11.4小结 (32)第四章软件设计 (33)4.1系统软件的设计思想 (33)4.2系统主程序的设计 (33)4.3系统子程序的设计 (33)4.3.1定时器/计数器子程序 (33)4.3.2 AD转换子程序 (36)4.3.3 LCD显示子程序 (37)4.3.4 中断服务子程序 (39)4.3.5 键盘子程序 (40)4.3.6 解除报警子程 (41)4.3.7 串行通信子程序 (41)第五章总结 (47)5.1毕业设计的主要工作情况及创新之处 (47)5.2系统改进及发展前景 (47)参考文献 (48)英文原文及翻译 (49)原文 (49)翻译 (57)致谢 (63)附录 (64)程序清单 (64)第一章绪论目前，社会对电力的需求越来越大。

MS7212多功能校准源目录安全要求 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 1 安全信息 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 1 安全标志 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 2 概述 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 2 特点 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 2 仪表外形 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 3 按键操作说明 - - - - - - - - - - - - - - - -- - - - - - - - - - - - - - - - - - - - - - 4 液晶显示 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 6使用说明 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 8 菜单选择 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 8 源输出操作示意图 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 10 源输出功能·电压输出 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 11 直流电压输出 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 11 阶梯电压输出 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 12 源输出功能·电流输出 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 14 直流电流输出 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 14阶梯电流输出 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 16 源输出功能·频率输出 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 18 测量功能·电压测量 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 20 测量功能·电流测量 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 21 测量功能·电阻测量 （通断测试） - - - - - - - - - - - - - - - - - - - - - - - - - - 23 测量功能·频率测量 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 24 测量功能·温度测量 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 24 RS232C数据接口 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 27 背光源显示 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 27 低电池电压指示 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 27 保险管的更换 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 27 电池的更换 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 28 技术指标 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 29 综合指标 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 29 准确度和分辨率 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 29 附件 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 33 其它 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 34MS7212多功能校准源安全要求· 在使用仪表时请仔细地阅读使用说明，特别要注意“警告”的内容。

BL0972交/直流电能计量芯片数据手册V1.0目录1、产品简述 (5)2、基本特征 (6)2.1主要特点 (6)2.2系统框图 (7)2.3管脚排列（TSSOP20） (7)2.4性能指标 (8)2.4.1电参数性能指标 (8)2.4.2极限范围 (9)3、工作原理 (10)3.1电流电压波形产生原理 (10)3.1.1PGA增益调整 (10)3.1.2相位补偿 (11)3.1.3通道偏置校正 (11)3.1.4通道增益校正 (12)3.1.5电流电压波形输出 (12)3.2有功功率计算原理 (13)3.2.1有功波形的选择 (14)3.2.2有功功率输出 (14)3.2.3有功功率校准 (14)3.2.4有功功率的防潜动 (15)3.2.5有功功率小信号补偿 (15)3.3有功能量计量原理 (16)3.3.1有功能量输出 (16)3.3.2有功能量输出选择 (16)3.3.3有功能量输出比例 (17)3.4电流电压有效值计算原理 (17)3.4.1有效值输出 (18)3.4.2有效值输入信号的设置 (18)3.4.3有效值刷新率的设置 (18)3.4.4电流电压有效值校准 (19)3.4.5有效值的防潜动 (19)3.5快速有效值检测原理 (20)3.5.1快速有效值输出 (20)3.5.2快速有效值输入选择 (21)3.5.3快速有效值累计时间和阈值 (21)3.5.4电网频率选择 (21)3.5.5快速有效值超限数据保存 (22)3.5.6过流指示 (22)3.5.7继电器控制 (22)3.6温度计量 (23)3.7.1线周期计量 (23)3.7.2线频率计量 (23)3.7.3相角计算 (24)3.7.4功率符号位 (24)3.8故障检测 (25)3.8.1过零检测 (25)3.8.2峰值超限 (25)3.8.3线电压跌落 (26)3.8.4过零超时 (27)3.8.5电源供电指示 (28)4、内部寄存器 (30)4.1电参量寄存器（只读） (30)4.2校表寄存器（外部写） (30)4.3OTP寄存器 (32)4.4模式寄存器 (33)4.4.1 MODE1寄存器 (33)4.4.2 MODE2寄存器 (33)4.4.3 MODE3寄存器 (34)4.5中断状态寄存器 (34)4.5.1 STATUS1寄存器 (34)4.5.2 STATUS3寄存器 (34)4.6校表寄存器详细说明 (34)4.6.1 通道PGA增益调整寄存器 (34)4.6.2 相位校正寄存器 (35)4.6.3 有效值增益调整寄存器 (35)4.6.4 有效值偏置校正寄存器 (36)4.6.5 有功小信号补偿寄存器 (36)4.6.7 防潜动阈值寄存器 (36)4.6.8 快速有效值相关设置寄存器 (37)4.6.9 过流报警及控制 (38)4.6.11 能量读后清零设置寄存器 (39)4.6.12 用户写保护设置寄存器 (39)4.6.13 软复位寄存器 (39)4.6.14 通道增益调整寄存器 (40)4.6.15 通道偏置调整寄存器 (40)4.6.16 有功功率增益调整寄存器 (40)4.6.17 有功功率偏置调整寄存器 (41)4.6.20 CF缩放比例寄存器 (41)4.7电参数寄存器详细说明 (42)4.7.1 波形寄存器 (42)4.7.2 有效值寄存器 (42)4.7.3 快速有效值寄存器 (42)4.7.7 电能脉冲计数寄存器 (43)4.7.8 波形夹角寄存器 (44)4.7.9 快速有效值保持寄存器 (44)4.7.11 线电压频率寄存器 (44)5、SPI通讯接口 (45)5.1概述 (45)5.2工作模式 (45)5.3帧结构 (45)5.4读出操作时序 (46)5.5写入操作时序 (47)5.6SPI接口的容错机制 (48)6、典型应用图 (49)7、封装信息 (50)1、产品简述BL0972是一颗内置时钟的单相交/直流电能计量芯片。

TSS721A在自动抄表系统中的应用作者：清华大学热能工程系 常东来江亿来源：《电子技术应用》摘要　介绍了一种新的仪表总线专用收发器芯片TSS721A的封装、基本功能以及应用电路连接。

该收发器应用于自动抄表系统中，可使系统的实现大为简化。

关键词　仪表总线收发器自动抄表系统　，自动抄表系统Automatic Meter Reading SystemAMRS　是一种不需要人员到达现场就能完成抄读各种计量仪表工作的管理系统。

在自动抄表系统中采用欧洲新型总线结构——仪表总线，将使所组成的系统性能价格比大为提高[1]。

采用新的仪表总线和相关技术的自动抄表系统具有一些显著的优点：通讯媒介可采用普通双绞线，总线极性可互换；可采用任意总线拓扑结构（星形、树形等），使系统布线施工简单、扩展灵活；总线工作不受任何从机接口或设备故障的影响；最大总线长度为1000公里（波特率≤9600波特时），并可以通过中继器扩大网络或系统的覆盖范围；可为用户计量仪表提供两种供电方式，即使停电也能保证系统正常工作；可满足现有所有的EMC、ESD、EMI要求。

TSS721A是美国德州仪器公司1999年初生产的一种用于仪表总线的专用收发器芯片，将其应用于自动抄表系统中，无疑使系统的性能价格比和可靠性再次提高。

本文结合应用对其加以介绍。

１ TSS721A的功能TSS721A是一种用于仪表总线的收发器集成芯片。

其内含的接口电路可以调节仪表总线结构中主从机之间的电平，可通过光电耦合器等隔离器件与总线连接，同时该收发器由总线供电，对从机不增加功率需求。

外形采用16脚双列直插封装，将整个数据发送功能集成于一体，其内部功能框图如图1所示。

芯片的外形封装如图2所示。

表1为各个管脚功能的简单说明。

该芯片具有其它一些主要功能[2]：①满足国际EN1434－3标准；②具有动态电平识别的接收逻辑；③通过电阻可调接收电流；④无极性连接；⑤防掉电功能；⑥可提供3.3V稳压源；⑦支持远程供电；⑧半双工下可达9600波特率；⑨支持UART协议；⑩从机可由总线或后备电池供电；只在数据传输时总线有效。

CTC121A芯片手册引言概述随着科技的迅猛发展，芯片作为电子产品的核心组件，发挥着日益重要的作用。

本文将深入研究CTC121A芯片手册，详细探讨该芯片的技术规格、功能特性以及在电路设计中的应用指南，旨在为工程师和设计者提供全面的信息。

正文内容1. 技术规格与基本信息1.1 芯片的基本结构首先，我们将介绍CTC121A芯片的基本结构，包括核心处理单元、存储器、输入输出端口等方面。

详细讨论各个部分的功能和相互关系，为用户提供清晰的硬件框架认知。

1.2 电气特性及工作参数在此小点中，我们将深入分析CTC121A芯片的电气特性，包括电压供应要求、电流消耗、时钟频率等参数。

这有助于用户正确配置芯片的电源和时序，确保其稳定可靠地工作。

1.3 温度范围与环境适应性CTC121A芯片在不同温度条件下的性能表现是至关重要的。

我们将研究芯片在不同温度范围内的工作情况，以及它对环境变化的适应性，帮助用户在各种应用场景中合理选用。

1.4 接口与通信协议芯片的接口和通信协议对于与外部系统的连接至关重要。

我们将详细探讨CTC121A芯片支持的各种接口类型，如UART、SPI、I2C 等，以及通信协议的配置与应用。

2. 功能特性与性能优势2.1 多核处理能力CTC121A芯片可能具备多核处理的能力，我们将深入研究多核系统的优势和应用场景。

这包括多核处理在计算密集型任务中的性能提升以及多核处理对功耗的影响等方面。

2.2 专业集成电路功能芯片通常会集成一系列专业功能模块，如模拟信号处理、数字信号处理等。

我们将详细介绍CTC121A芯片的专业集成电路功能，并分析其在不同应用场景中的优越性能。

2.3 低功耗设计与能效优化在当前注重能效的趋势下，我们将探讨CTC121A芯片的低功耗设计原理，包括功耗优化的方法、待机模式的配置以及在不同工作负载下的能效表现。

2.4 安全与可靠性特性在现代电子设备中，安全性和可靠性是至关重要的考虑因素。

M-Bus仪表总线原理研究（完整版）doc资料M-Bus仪表总线原理研究Research on Principle of Instrument Bus M-Bus摘要:本文详细的介绍了M-Bus总线的网络层次结构、数据传送工作原理及网络协议等重要内容，并对M-Bus系统的总线收发器TSS721作了详尽的阐述。

在应用方面，公共事业仪表通过扩展M-Bus总线，使其具有与M-Bus仪表总线通讯的功能，从而实现远程抄表。

关键词：M-Bus 总线; 总线收发器; 远程抄表Abstract：This paper presents the industrial background of M-Bus and gives a detailed description about the important content of the hierarchy network structure、data transmission principle and network protocol of M-Bus. The M-Bus transceiver TSS721 is also introduced at the same time . For the application of M-Bus, the remote reading of utility meters is a good example.Key words：Meters bus；application；remotely coping meters1 M-Bus总线的提出对于一个远程抄表系统来讲，总线上传输的数据就是终端用户所消费的水、电、气等重要数据,因此对总线的抗外部干扰性要求非常高，要能抵抗各种容性、感性的偶合干扰，所有从设备及从设备和主设备之间都相互隔离。

同时又要求组网成本相对较低，传输线无须使用屏蔽电缆，而且为节约成本，要采用远程供电的方式给从设备提供电源，以尽可能减少元器件的使用。

123413141516RXIRISGNDBUSL1RIDDSTCVBBUSL2D PACKAGE(TOP VIEW)567101112VSVDDRXTXISCPF89BA TTXTSS721A SLAS222B–APRIL1999–REVISED NOVEMBER2010METER-BUS TRANSCEIVERCheck for Samples:TSS721AFEATURES•Meter-Bus Transceiver(for Slave)MeetsStandard EN1434-3•Receiver Logic With Dynamic LevelRecognition•Adjustable Constant-Current Sink via Resistor•Polarity Independent•Power-Fail Function•Module Supply Voltage Switch• 3.3-V Constant Voltage Source•Remote Powering•Up to9600Baud in Half Duplex for UARTProtocol•Slave Power Support–Supply From Meter-Bus via Output VDD–Supply From Meter-Bus via Output VDD orFrom Backup Battery–Supply From Battery–Meter-Bus Active forData Transmission OnlyDESCRIPTIONTSS721A is a single chip transceiver developed for Meter-Bus standard(EN1434-3)applications.The TSS721A interface circuit adjusts the different potentials between a slave system and the Meter-Bus master.The connection to the bus is polarity independent and supports full galvanic slave isolation with optocouplers.The circuit is supplied by the master via the bus.Therefore,this circuit offers no additional load for the slave battery.A power-fail function is integrated.The receiver has dynamic level recognition,and the transmitter has a programmable current sink.A3.3-V voltage regulator,with power reserve for a delayed switch off at bus fault,is integrated.Table1.ORDERING INFORMATION(1)(2)T A PACKAGE ORDERABLE PART NUMBER 0°C to70°C SOIC–D Reel of2500TSS721ADR(1)For the most current package and ordering information,see the Package Option Addendum at the end of this document,or see the TIweb site at .(2)Package drawings,thermal data,and symbolization are available at /packaging.Please be aware that an important notice concerning availability,standard warranty,and use in critical applications of TexasInstruments semiconductor products and disclaimers thereto appears at the end of this data sheet.PRODUCTION DATA information is current as of publication date.Copyright©1999–2010,Texas Instruments Incorporated Products conform to specifications per the terms of the TexasInstruments standard warranty.Production processing does notnecessarily include testing of all parameters.BAT RIDDSTCVS VDD VBPF BUSL1 TXGND RIS BUSL2 TXIRX RXI SCTSS721ASLAS222B–APRIL1999–REVISED FUNCTIONAL DESCRIPTIONFigure1.Functional SchematicTable2.Terminal FunctionsTERMINALDESCRIPTIONNAME NO.BUSL21Meter-BusVB2Differential bus voltage after rectifierSTC3Support capacitorRIDD4Current adjustment inputPF5Power fail outputSC6Sampling capacitorTXI7Data output invertedTX8Data outputBAT9Logic level adjustVS10Switch for bus or battery supply outputVDD11Voltage regulator outputRX12Data inputRXI13Data input invertedRIS14Adjust input for modulation currentGND15GroundBUSL116Meter-Bus2Submit Documentation Feedback Copyright©1999–2010,Texas Instruments IncorporatedProduct Folder Link(s):TSS721AVBBUSL1BUSL2V TV V TXV I SC C = 30 pF typ BUSL1-BUSL2V = 25V ,f = 1 MHzB meas I =SCdisharge I SCcharge40 (typ)TSS721ASLAS222B –APRIL 1999–REVISED NOVEMBER 2010Data Transmission,Master to SlaveThe mark level on the bus lines V BUS =MARK is defined by the difference of BUSL1and BUSL2at the slave.It is dependent on the distance of Master to Slave,which affects the voltage drop on the wire.To make the receiver independent,a dynamic reference level on the SC pin is used for the voltage comparator TC3(see Figure 2).Figure 2.Data Transmission,Master to SlaveA capacitor C SC at pin SC is charged by a current I SCcharge and is discharged with a current I SCdischarge where:(1)This ratio is necessary to run any kind of UART protocol independent of the data contents.(for example,if an 11-bit UART protocol is transmitted with all data bits at 0and only the stop bit at 1).There must be sufficient time to recharge the capacitor C SC .The input level detector TC3detects voltage modulations from the master,V BUS =SPACE/MARK conditions,and switches the inverted output TXI and the non-inverted output TX.Copyright ©1999–2010,Texas Instruments Incorporated Submit Documentation Feedback3Product Folder Link(s):TSS721AVBBUSL1GNDBUSL2R RISRISRX RXI V I BUSV RXIV RXI = I + I MC MS CS3I MC )RIS W V =Voltage on pin RIS R = Programming resistor I = Programmable current I = Modulation currentI = Modulation supply current (220 µA typ)RIS RIS CS3MC MS R =RIS=V RIS I CS3V RISI –I MC MSTSS721ASLAS222B –APRIL 1999–REVISED NOVEMBER 2010Data Transmission,Slave to MasterThe device uses current modulation to transmit information from the slave to the master while the bus voltage remains constant.The current source CS3modulates the bus current and the master detects the modulation.The constant current source CS3is controlled by the inverted input RXI or the non-inverted input RX.The current source CS3can be programmed by an external resistor R RIS .The modulation supply current I MS flows in addition to the current source CS3during the modulation time.Figure 3.Data Transmission,Slave to MasterBecause the TSS721A is configured for half-duplex only,the current modulation from RX or RXI is repeated concurrently as ECHO on the outputs TX and TXI.If the slave,as well as the master,is trying to send information via the lines,the added signals appear on the outputs TX and TXI,which indicates the data collision to the slave (see Figure 1).The bus topology requires a constant current consumption by each connected slave.To calculate the value of the programming resistor R RIS ,use the formula shown in Figure 4.Figure 4.Calculate Programming Resistor R RIS4Submit Documentation FeedbackCopyright ©1999–2010,Texas Instruments IncorporatedProduct Folder Link(s):TSS721AR= 25 RID VRIDDISTC= 25VRIDDI+ ISTC_use IC1I(BUS34567(V)STC812TSS721A SLAS222B–APRIL1999–REVISED NOVEMBER2010 Slave Supply,3.3VThe TSS721A has an internal3.3-V voltage regulator.The output power of this voltage regulator is supplied by the storage capacitor C STC at pin STC.The storage capacitor C STC at pin STC is charged with constant current I STC_use from the current source CS1.The maximum capacitor voltage is limited to REF1.The charge current I STC has to be defined by an external resistor at pin RIDD.The adjustment resistor R RIDD can be calculated using Equation2.(2)Where,I STC=current from current source CS1I STC_use=charge current for support capacitorI CI=internal currentV RIDD=voltage on pin RIDDR RIDD=value of adjustment resistorThe voltage level of the storage capacitor C STC is monitored with comparator TC1.Once the voltage V STC reaches V VDD_on,the switch S VDD connects the stabilized voltage V VDD to pin VDD.VDD is turned off if the voltage V STC drops below the V VDD_off level.Voltage variations on the capacitor C STC create bus current changes(see Figure5).Figure5.Single Mode Bus LoadAt a bus fault the shut down time of VDD(t off)in which data storage can be performed depends on the system current I VDD and the value of capacitor C STC.See Figure6,which shows a correlation between the shutdown of the bus voltage V BUS and V DD_off and t off for dimensioning the capacitor.The output VS is meant for slave systems that are driven by the bus energy,as well as from a battery should the bus line voltage fail.The switching of VS is synchronized with VDD and is controlled by the comparator TC1.An external transistor at the output VS allows switching from the Meter-Bus remote supply to battery.Copyright©1999–2010,Texas Instruments Incorporated Submit Documentation Feedback5Product Folder Link(s):TSS721AV V V V V V STCVDDoffoff STC VDD CI1V –V t =C I +I TSS721ASLAS222B –APRIL 1999–REVISED NOVEMBER 2010Power On/OffFigure 6.Power On/Off TimingPower Fail FunctionBecause of the rectifier bridge BR at the input,BUSL1,and BUSL2,the TSS721A is polarity independent.The pin VB to ground (GND)delivers the bus voltage V VB less the voltage drop over the rectifier BR.The voltage comparator TC2monitors the bus voltage.If the voltage V VB >V STC +0.6V,then the output PF =1.The output level PF =0(power fail)provides a warning of a critical voltage drop to the microcontroller to save the data immediately.6Submit Documentation FeedbackCopyright ©1999–2010,Texas Instruments IncorporatedProduct Folder Link(s):TSS721ATSS721A SLAS222B–APRIL1999–REVISED NOVEMBER2010ABSOLUTE MAXIMUM RATINGSover operating free-air temperature range(unless otherwise noted)V MB Voltage,BUSL1to BUSL2±50VRX and RXI–0.3V to5.5VV I Input voltage rangeBAT–0.3V to5.5VT J Operating junction temperature range–25°C to150°CT A Operating free-air temperature range–25°C to85°CT STG Storage temperature range–65°C to150°C Power derating factor,junction to ambient8mW/°C RECOMMENDED OPERATING CONDITIONS(1)MIN MAX UNITReceiver10.842V MB Bus voltage,|BUSL2–BUSL1|VTransmitter1242VB(receive mode)9.3V I Input voltage VBAT(2) 2.5 3.8R RIDD RIDD resistor1380kΩR RIS RIS resistor100ΩT A Operating free-air temperature–2585°C(1)All voltage values are measured with respect to the GND terminal unless otherwise noted.(2)V BAT(max)≤V STC–1VELECTRICAL CHARACTERISTICS(1)over operating free-air temperature range(unless otherwise noted)PARAMETER TEST CONDITIONS MIN TYP MAX UNIT ΔV BR Voltage drop at rectifier BR I BUS=3mA 1.5VVoltage drop at currentΔV CS1R RIDD=13kΩ 1.8V source CS1R RIDD=13kΩ3V STC=6.5V,I BUS BUS current mAI MC=0mA R=30kΩ 1.5RIDDΔI BUS BUS current accuracyΔV BUS=10V,I MC=0mA,R RIDD=13kΩto30kΩ2%I CC Supply current V STC=6.5V,I MC=0mA,V BAT=3.8V,R RIDD=13kΩ(2)650µAV STC=6.5V,I MC=0mA,V BAT=3.8V,R RIDD=13kΩ,I CI1CI1current350µAV BUS=6.5V,RX/RXI=off(2)I BAT BAT current–0.50.5µAI BAT+I VDD BAT plus VDD current V BUS=0V,V STC=0V–0.50.5µAV VDD VDD voltage–I VDD=1mA,V STC=6.5V 3.1 3.4VR VDD VDD resistance–I VDD=2to8mA,V STC=4.5V5ΩV DD=on,VS=on 5.6 6.4V STC STC voltage V DD=off,VS=off 3.8 4.3VI VDD<I STC_use 6.57.5R RIDD=30kΩ0.65 1.1I STC_use STC current V STC=5V mAR RIDD=13kΩ 1.85 2.4V RIDD RIDD voltage R RIDD=30kΩ 1.23 1.33VV VS VS voltage V DD=on,I VS=–5µA V STC–0.4V STC VR VS VS resistance V DD=off0.31MΩV VB=V STC+0.8V,I PF=–100µA V BAT–0.6V BATV PF PF voltage V STC=6.5V V VB=V STC+0.3V,I PF=1µA00.6VV VB=V STC+0.3V,I PF=5µA00.9(1)All voltage values are measured with respect to the GND terminal,unless otherwise noted.(2)Inputs RX/RXI and outputs TX/TXI are open,I CC=I CI1+I CI2Copyright©1999–2010,Texas Instruments Incorporated Submit Documentation Feedback7Product Folder Link(s):TSS721ATSS721ASLAS222B–APRIL1999–REVISED ELECTRICAL CHARACTERISTICS(1)(continued)over operating free-air temperature range(unless otherwise noted)PARAMETER TEST CONDITIONS MIN TYP MAX UNIT t on Turn-on time C STC=50µF,Bus voltage slew rate:1V/µs3sRECEIVER SECTION ELECTRICAL CHARACTERISTICS(1)over operating free-air temperature range(unless otherwise noted)PARAMETER TEST CONDITIONS MIN TYP MAX UNITMARK MARK–V T See Figure2V–8.2 5.7V SC SC voltage V VB VI SCcharge SC charge current V SC=24V,V VB=36V–15–40µA–0.033×I SCdischarge SC discharge current V SC=V VB=24V0.3µAI SCchargeHigh-level output voltage V BAT–V OH I TX/I TXI=–100µA(see Figure2)V BAT V (TX,TXI)0.6I TX/I TXI=100µA00.5Low-level output voltageV OL V (TX,TXI)I=1.1mA0 1.5TXI TXTX,TXI current V TX=7.5,V VB=12V,V STC=6V,V BAT=3.8V10µAI TXI(1)All voltage values are measured with respect to the GND terminal,unless otherwise noted.TRANSMITTER SECTION ELECTRICAL CHARACTERISTICS(1)over operating free-air temperature range(unless otherwise noted)PARAMETER TEST CONDITIONS MIN TYP MAX UNIT I MC MC voltage R RIS=100Ω11.519.5mAR RIS=100Ω 1.4 1.7V RIS RIS voltage VR RIS=1000Ω 1.5 1.8V BAT–V IH High-level input voltage(RX,RXI)See Figure3,see(2) 5.5V0.8V IL Low-level input voltage(RX,RXI)See Figure300.8VV RX=V BAT=3V,V VB=V STC=0V-0.50.5I RX RX currentµAV RX=0V,V BAT=3V,V STC=6.5V-10-40V RXI=V BAT=3V,V VB=V STC=0V1040I RXI RXI currentµAV RXI=V BAT=3V,V STC=6.5V1040(1)All voltage values are measured with respect to the GND terminal,unless otherwise noted.(2)V IH(max)=5.5V is valid only when V STC>=6.5V.8Submit Documentation Feedback Copyright©1999–2010,Texas Instruments IncorporatedProduct Folder Link(s):TSS721AMeter-BusC - system stabilising capacitor C - support capacitor C - sampling capacitorC - stabilising capacitor (100 nF)C :C >= 4:1SSC STC SC VDD STC VDD R - slave-current adjustment resistor R - modulation-current resistor RL1,RL2 - protection resistorsR - discharge resistor (100 k recommended)RIDD RIS load W TSS721ASLAS222B –APRIL 1999–REVISED NOVEMBER 2010APPLICATION INFORMATIONNOTE:Transistor T1should be a BSS84.Figure 7.Basic Application Circuit Using Support Capacitor C STC >50µFFigure 8.Basic Application Circuit for Supply From BatteryCopyright ©1999–2010,Texas Instruments Incorporated Submit Documentation Feedback9Product Folder Link(s):TSS721ATSS721ASLAS222B–APRIL1999–REVISED Meter-Bus NOTE:R DSon of the transistor T1(BSS84)at low battery voltage must be considered during application design.Figure9.Basic Applications for Different Supply ModesFigure10.Basic Optocoupler Application10Submit Documentation Feedback Copyright©1999–2010,Texas Instruments IncorporatedProduct Folder Link(s):TSS721A18-Dec-2015 PACKAGING INFORMATION(1) The marketing status values are defined as follows:ACTIVE: Product device recommended for new designs.LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.PREVIEW: Device has been announced but is not in production. Samples may or may not be available.OBSOLETE: TI has discontinued the production of the device.(2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check /productcontent for the latest availability information and additional product content details.TBD: The Pb-Free/Green conversion plan has not been defined.Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement thatlead not exceed 0.1% by weight in homogeneous materials. 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基于云平台管理系统的智能表数据采集器的设计杜博;吴琼;杜景飞;苏全志;李迪星;张秋月【摘要】近年来,“多表合一”工程得到了国家高度重视,在国家政策的号召下,国家电网公司利用现有用电信息采集系统,积极建设“多表合一”.依据最新的T/CEC 122-2016《电、水、气、热能源计量管理系统》系列标准进行设计基于云平台的智能表数据采集器,并从总体方案、主要硬件设计和主要软件设计等几个方面进行了介绍.【期刊名称】《电测与仪表》【年(卷),期】2018(055)007【总页数】5页(P105-109)【关键词】能源计量管理系统;智能表;M-Bus;RFID【作者】杜博;吴琼;杜景飞;苏全志;李迪星;张秋月【作者单位】哈尔滨电工仪表研究所有限公司,哈尔滨150028;哈尔滨电工仪表研究所有限公司,哈尔滨150028;哈尔滨电工仪表研究所有限公司,哈尔滨150028;哈尔滨电工仪表研究所有限公司,哈尔滨150028;哈尔滨电工仪表研究所有限公司,哈尔滨150028;哈尔滨电工仪表研究所有限公司,哈尔滨150028【正文语种】中文【中图分类】TM9330 引言近几年，国家相关部门非常重视公共服务“多表合一”推进工作，为促进能源互联网发展，国家发展改革委、国家能源局、工业和信息化部联合与2016年制定了《关于推进“互联网+”智慧能源发展的指导意见》，并在指导意见关于促进智能终端及接入设施的普及应用的内容中提出“丰富智能终端高级测量系统的实施功能，促进水、气、热、电的远程自动集采集抄，实现多表合一[1]”。

在国家政策的号召下，国家电网公司率先将“多表合一”建设作为一项重点工程来推进，进一步落实“便民、为民、惠民”的服务，综合利用和升级国家电网公司用户用电信息采集系统平台，实现电、水、气、热多表集抄，提升社会公共事业服务水平。

本文依据最新的T/CEC122-2016《电、水、气、热能源计量管理系统》系列标准进行设计智能表数据采集器，实现了电、水、气、热四表数据采集、管理及传输功能。

ch7217a中文规格书ch7217a中文规格书是一个关于某种设备或产品详细参数和功能描述的文件。

它通常用于在产品开发和生产过程中，确保各个团队和厂商理解和遵守相同的要求和标准。

下面是一个关于ch7217a中文规格书的参考内容：1. 产品描述：ch7217a是一款数字信号处理器，可以实现高性能音频处理功能。

它具有8个输入通道和8个输出通道，支持多种音频输入和输出格式。

2. 技术规格：- 输入和输出通道：8个- 输入和输出格式：PCM、I2S、SPDIF等- 采样率：支持最高192kHz采样率- 位深度：支持最高24位- 主频：可配置，最高达1GHz- 存储容量：内置128MB Flash和64MB RAM3. 功能特点：- 高性能处理能力：采用先进的数字信号处理算法，实现高清晰度音频处理，包括混响、均衡器、降噪等功能。

- 多通道输入输出：支持最多8个通道的音频输入和输出，满足多声道音频处理的需求。

- 低功耗设计：采用先进的低功耗技术和智能节能策略，降低产品能耗，延长续航时间。

- 灵活的配置选项：提供多种配置选项，可根据不同需求进行灵活配置，满足不同客户的需求。

- 易于集成：提供适用于不同操作系统的驱动程序和软件开发包，方便产品集成和开发。

4. 应用领域：- 智能音箱：ch7217a可以作为智能音箱的音频处理芯片，实现高保真音效和多通道音频处理功能。

- 录音设备：ch7217a可以用于专业录音设备，提供高品质录音和音频处理能力。

- 多媒体播放器：ch7217a可以用于多媒体播放器，增强音频输出效果。

- 音频处理设备：ch7217a还可以作为专业音频处理设备的核心芯片，提供高性能音频处理功能。

5. 质量标准和认证：- 符合ISO 9001质量管理体系标准；- 符合相关CE、FCC等认证要求。

综上所述，ch7217a中文规格书详细描述了该产品的技术规格、功能特点、应用领域和质量标准。

这些规格对于产品研发、生产和销售具有指导作用，可以确保产品符合客户需求、达到预期性能，并满足相关认证要求。

TSS721A技术资料总结一，芯片简介TSS721A是一种用于仪表总线的收发器集成芯片，其内含的接口电路可以调节仪表总线结构中主从机的电平，可通过光耦等隔离器件与总线连接，通过数据收发器由总线供电。

芯片封装采用DIP16封装，将整个数据发送功能集成于一体，内部功能框图如图1所示，管脚功能介绍如下：图11，满足国际EN1434-3标准2，具有动态电平识别的接收电流3，通过限流电阻可调接收电流4，无极性连接5，放掉电功能6，可提供3.3.V稳压源7，支持远程供电，从机可由总线或电池供电8，半双工下可达9600 Baud rate9，支持UART协议，只在数据传输时总线有效二，管脚功能三，数据传输模式MBUS传输原理1，主——>从此模式下采用电压调制传输数据，总线电流保持不变。

即主机发送的数据码流是一种电压脉冲序列，用+36V标识逻辑‘1’，用+24V标识逻辑‘0’。

在稳态时，线路将保持‘1’状态。

如图2所示：图2总线电压Vbus=MARK（标识值）是由从机BUSL1和BUSL2间压差定义的，连接在管脚SC上的电容Csc的充放电流是不同的，存在以下关系：I SCcharge =ISCdischarge/40这个比例关系是独立于数据内容运行任意UART协议所必须的条件（例如传输采用11位UART协议，当所有数据只有停止位是1.其他都是0），必须有足够的时间对电容Csc进行再充电，内部电压比较器TC3检测来自主机的调制电压，并根据电压VBUS=SPACE（空值）或MARK（标识值）来开关正端输出TX和反向端输出TXI，输出数据给从机。

2，从——>主在此模式下使用总线电流调制传输据，总线电压保持不变，即从机发送的数据码流是一种电流脉冲序列，通常用1.5mA表示逻辑‘1’，当传输‘0’时，由从机控制使电流值增加到11~20mA。

在稳态时，线路值持续‘1’状态，当从机接收信号时，其电流应处于稳态‘1’，在接收信号时，其电压值的变化所导致的电流变化不应超过0.2%/V。