- 您現(xiàn)在的位置:買賣IC網(wǎng) > PDF目錄68811 > 71M6543F-IGT/F (MAXIM INTEGRATED PRODUCTS INC) SPECIALTY ANALOG CIRCUIT, PQFP100 PDF資料下載
參數(shù)資料
| 型號(hào): | 71M6543F-IGT/F |
| 廠商: | MAXIM INTEGRATED PRODUCTS INC |
| 元件分類: | 模擬信號(hào)調(diào)理 |
| 英文描述: | SPECIALTY ANALOG CIRCUIT, PQFP100 |
| 封裝: | LEAD FREE, LQFP-100 |
| 文件頁(yè)數(shù): | 150/157頁(yè) |
| 文件大小: | 2178K |
| 代理商: | 71M6543F-IGT/F |
第1頁(yè)第2頁(yè)第3頁(yè)第4頁(yè)第5頁(yè)第6頁(yè)第7頁(yè)第8頁(yè)第9頁(yè)第10頁(yè)第11頁(yè)第12頁(yè)第13頁(yè)第14頁(yè)第15頁(yè)第16頁(yè)第17頁(yè)第18頁(yè)第19頁(yè)第20頁(yè)第21頁(yè)第22頁(yè)第23頁(yè)第24頁(yè)第25頁(yè)第26頁(yè)第27頁(yè)第28頁(yè)第29頁(yè)第30頁(yè)第31頁(yè)第32頁(yè)第33頁(yè)第34頁(yè)第35頁(yè)第36頁(yè)第37頁(yè)第38頁(yè)第39頁(yè)第40頁(yè)第41頁(yè)第42頁(yè)第43頁(yè)第44頁(yè)第45頁(yè)第46頁(yè)第47頁(yè)第48頁(yè)第49頁(yè)第50頁(yè)第51頁(yè)第52頁(yè)第53頁(yè)第54頁(yè)第55頁(yè)第56頁(yè)第57頁(yè)第58頁(yè)第59頁(yè)第60頁(yè)第61頁(yè)第62頁(yè)第63頁(yè)第64頁(yè)第65頁(yè)第66頁(yè)第67頁(yè)第68頁(yè)第69頁(yè)第70頁(yè)第71頁(yè)第72頁(yè)第73頁(yè)第74頁(yè)第75頁(yè)第76頁(yè)第77頁(yè)第78頁(yè)第79頁(yè)第80頁(yè)第81頁(yè)第82頁(yè)第83頁(yè)第84頁(yè)第85頁(yè)第86頁(yè)第87頁(yè)第88頁(yè)第89頁(yè)第90頁(yè)第91頁(yè)第92頁(yè)第93頁(yè)第94頁(yè)第95頁(yè)第96頁(yè)第97頁(yè)第98頁(yè)第99頁(yè)第100頁(yè)第101頁(yè)第102頁(yè)第103頁(yè)第104頁(yè)第105頁(yè)第106頁(yè)第107頁(yè)第108頁(yè)第109頁(yè)第110頁(yè)第111頁(yè)第112頁(yè)第113頁(yè)第114頁(yè)第115頁(yè)第116頁(yè)第117頁(yè)第118頁(yè)第119頁(yè)第120頁(yè)第121頁(yè)第122頁(yè)第123頁(yè)第124頁(yè)第125頁(yè)第126頁(yè)第127頁(yè)第128頁(yè)第129頁(yè)第130頁(yè)第131頁(yè)第132頁(yè)第133頁(yè)第134頁(yè)第135頁(yè)第136頁(yè)第137頁(yè)第138頁(yè)第139頁(yè)第140頁(yè)第141頁(yè)第142頁(yè)第143頁(yè)第144頁(yè)第145頁(yè)第146頁(yè)第147頁(yè)第148頁(yè)第149頁(yè)當(dāng)前第150頁(yè)第151頁(yè)第152頁(yè)第153頁(yè)第154頁(yè)第155頁(yè)第156頁(yè)第157頁(yè)
71M6543F/H and 71M6543G/GH Data Sheet
92
2008–2011 Teridian Semiconductor Corporation
v1.2
GAIN_ADJ4
0x44
IADC6-IADC7
VREF in 71M6xx3 and Shunt
(Phase C)
In the demonstration code, the shape of the temperature compensation second-order parabolic curve is
determined by the values stored in the PPMC (1
st order coefficient) and PPMC2 (2nd order coefficient),
which are typically setup by the MPU at initialization time from values that are stored in EEPROM.
To disable temperature compensation in the demonstration code, PPMC and PPMC2 are both set to zero
for each of the five GAIN_ADJx channels. To enable temperature compensation, the PPMC and PPMC2
coefficients are set with values that match the expected temperature variation of the shunt current sensor
(if required) and the corresponding VREF voltage reference (summed together).
The shunt sensor requires a second order polynomial compensation which is determined by the PPMC
and PPMC2 coefficients for the corresponding current measurement channel. The corresponding VREF
voltage reference also requires the PPMC and PPMC2 coefficients to match the second order
temperature behavior of the voltage reference. The PPMC and PPMC2 values associated with the shunt
and with the corresponding VREF are summed together to obtain the compensation coefficients for a
given current-sensing channel (i.e., the 1
st order PPMC coefficients are summed together, and the 2nd
order PPMC2 coefficients are summed together).
In the 71M6543F and 71M6543G, the required VREF compensation coefficients PPMC and PPMC2 are
calculated from readable on-chip non-volatile fuses (see 4.5.2 Temperature Coefficients for the
71M6543F). These coefficients are designed to achieve ±40 ppm/°C for VREF in the 71M6543F and
71M6543G. PPMC and PPMC2 coefficients are similarly calculated for the 71M6xx3 remote sensor
For the 71M6543H and 71M6543GH (±0.1% energy accuracy), coefficients specific to each individual
device can be calculated from values read from additional on-chip fuses that characterize the VREF
behavior of each individual part across industrial temperatures (see 4.5.3 Temperature Coefficients for
the 71M6543H). The resulting tracking of the reference VREF voltage is within ±10 ppm/°C.
For the current channels, to determine the PPMC and PPMC2 coefficients for the shunt current
sensors, the designer must either know the average temperature curve of the shunt from its
manufacturer’s data sheet or obtain these coefficients by laboratory characterization of the shunt used
in the design.
4.5.6
Temperature Compensation of VREF and Current Transformers
This section discusses metrology temperature compensation for meter designs where Current
Transformer (CT) sensors are used, as shown in Figure 32.
Sensors that are directly connected to the 71M6543 are affected by the voltage variation in the 71M6543
VREF due to temperature. The VREF in the 71M6543 can be compensated digitally using a second-
order polynomial function of temperature. The 71M6543 features a temperature sensor for the purposes
of temperature compensating its VREF. The compensation computations must be implemented in MPU
firmware and written to the corresponding GAIN_ADJx CE RAM location.
Referring to Figure 32, the VADC8 (VA), VADC9 (VB) and VADC10 (VC) voltage sensors are directly
connected to the 71M6543. Thus, the precision of the voltage sensors is primarily affected by VREF in the
71M6543. The temperature coefficient of the resistors used to implement the voltage dividers for the voltage
sensors (see Figure 27) determine the behavior of the voltage division ratio with respect to temperature. It is
recommended to use resistors with low temperature coefficients, while forming the entire voltage divider
using resistors belonging to the same technology family, in order to minimize the temperature dependency of
the voltage division ratio. The resistors must also have suitable voltage ratings.
The Current Transformers are directly connected to the 71M6543 and are therefore primarily affected by the
VREF temperature dependency in the 71M6543. For best performance, it is recommended to use the
differential signal conditioning circuit, as shown in Figure 29, to connect the CTs to the 71M6543. Current
transformers may also require temperature compensation. The copper wire winding in the CT has dc
resistance with a temperature coefficient, which makes the voltage delivered to the burden resistor
temperature dependent, and the burden resistor also has a temperature coefficient. Thus, each CT sensor
channel needs to compensate for the 71M6543 VREF, and optionally for the temperature dependency of the
CT and its burden resistor depending on the required accuracy class.
相關(guān)PDF資料 |
PDF描述 |
|---|---|
| 71M6543H-IGTR/F | SPECIALTY ANALOG CIRCUIT, PQFP100 |
| 71M6543F-IGTR/F | SPECIALTY ANALOG CIRCUIT, PQFP100 |
| 71M6543H-IGT/F | SPECIALTY ANALOG CIRCUIT, PQFP100 |
| 71M6543G-IGTR/F | SPECIALTY ANALOG CIRCUIT, PQFP100 |
| 71M6543GH-IGTR/F | SPECIALTY ANALOG CIRCUIT, PQFP100 |
相關(guān)代理商/技術(shù)參數(shù) |
參數(shù)描述 |
|---|---|
| 71M6543F-IGTR/F | 功能描述:計(jì)量片上系統(tǒng) - SoC Precision Energy Meter IC RoHS:否 制造商:Maxim Integrated 核心:80515 MPU 處理器系列:71M6511 類型:Metering SoC 最大時(shí)鐘頻率:70 Hz 程序存儲(chǔ)器大小:64 KB 數(shù)據(jù) RAM 大小:7 KB 接口類型:UART 可編程輸入/輸出端數(shù)量:12 片上 ADC: 安裝風(fēng)格:SMD/SMT 封裝 / 箱體:LQFP-64 封裝:Reel |
| 71M6543FT-IGT/F | 制造商:Maxim Integrated Products 功能描述:ENERGY METER ICS - Rail/Tube |
| 71M6543FT-IGTR/F | 制造商:Maxim Integrated Products 功能描述:3-PHASE SOC, 64KB FLASH, PRES TEMP SENSOR - Tape and Reel |
| 71M6543G | 制造商:MAXIM 制造商全稱:Maxim Integrated Products 功能描述:Selectable Gain of 1 or 8 for One Current Energy Meter ICs Metrology Compensation |
| 71M6543GH | 制造商:未知廠家 制造商全稱:未知廠家 功能描述:電表IC |
發(fā)布緊急采購(gòu),3分鐘左右您將得到回復(fù)。