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71M6543 Demo Board
USER’S MANUAL
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent
licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
Maxim Integrated Products, Inc. 160 Rio Robles, San Jose, CA 95134 USA 1-408-601-1000
2012 Maxim Integrated Products is a registered trademark of Maxim Integrated Products, Inc.
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71M6543
Polyphase Energy Meter IC
DEMO BOARD REV 4.0 and 5.0
USER’S MANUAL
71M6543 Demo Board User’s Manual
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Table of Contents
1 GETTING STARTED................................................................................................................................................ 7
1.1 General .................................................................................................................................................................... 7
1.2 Safety and ESD Notes ............................................................................................................................................ 7
1.3 Demo Kit Contents ................................................................................................................................................. 8
1.4 Demo Board Versions ............................................................................................................................................ 8
1.5 Compatibility ........................................................................................................................................................... 8
1.6 Suggested Equipment not Included ..................................................................................................................... 8
1.7 Demo Board Test Setup ......................................................................................................................................... 9
1.7.1 Power Supply Setup ........................................................................................................................................ 10
1.7.2 Cables for Serial Communication .................................................................................................................... 10
1.7.3 Checking Operation ......................................................................................................................................... 11
1.7.4 Serial Connection Setup .................................................................................................................................. 11
1.8 Using the Demo Board ......................................................................................................................................... 12
1.8.1 Serial Command Language ............................................................................................................................. 13
1.8.2 Using the Demo Board for Energy Measurements .......................................................................................... 19
1.8.3 Adjusting the Kh Factor for the Demo Board ................................................................................................... 19
1.8.4 Adjusting the Demo Boards to Different SHUNT Resistors ............................................................................. 19
1.8.5 Using the Pre-Amplifier ................................................................................................................................... 19
1.8.6 Using Current Transformers (CTs) .................................................................................................................. 19
1.8.7 Adjusting the Demo Boards to Different Voltage Dividers ............................................................................... 19
1.9 Calibration Parameters ........................................................................................................................................ 20
1.9.1 General Calibration Procedure ........................................................................................................................ 20
1.9.2 Calibration Macro File ..................................................................................................................................... 21
1.9.3 Updating the Demo Code (hex file) ................................................................................................................. 21
1.9.4 Updating Calibration Data in Flash or EEPROM ............................................................................................. 21
1.9.5 Loading the Code for the 71M6543F into the Demo Board ............................................................................. 22
1.9.6 The Programming Interface of the 71M6543F ................................................................................................. 23
1.10 Demo Code ........................................................................................................................................................ 24
1.10.1 Demo Code Description ............................................................................................................................... 24
1.10.2 Demo Code Versions ................................................................................................................................... 24
1.10.3 Important MPU Addresses ........................................................................................................................... 24
1.10.4 LSB Values in CE Registers ........................................................................................................................ 31
1.10.5 Calculating IMAX and Kh ............................................................................................................................. 31
1.10.6 Determining the Type of 71M6x0x ............................................................................................................... 32
1.10.7 Communicating with the 71M6X0x .............................................................................................................. 33
1.10.8 Bootloader Feature ...................................................................................................................................... 33
2 APPLICATION INFORMATION ............................................................................................................................. 35
2.1 Calibration Theory ................................................................................................................................................ 35
2.1.1 Calibration with Three Measurements ............................................................................................................. 35
2.1.2 Calibration with Five Measurements ............................................................................................................... 37
2.2 Calibration Procedures ........................................................................................................................................ 38
2.2.1 Calibration Equipment ..................................................................................................................................... 38
2.2.2 Detailed Calibration Procedures ...................................................................................................................... 38
2.2.3 Calibration Procedure with Three Measurements ........................................................................................... 39
2.2.4 Calibration Procedure with Five Measurements .............................................................................................. 40
2.2.5 Calibration Spreadsheets ................................................................................................................................ 40
2.2.6 Compensating for Non-Linearities ................................................................................................................... 42
2.3 Temperature Compensation ................................................................................................................................ 43
2.3.1 Error Sources .................................................................................................................................................. 43
2.3.2 Software Features for Temperature Compensation ........................................................................................ 44
2.3.3 Calculating Parameters for Compensation ...................................................................................................... 45
2.4 Testing the Demo Board ...................................................................................................................................... 48
71M6543 Demo Board User’s Manual
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2.4.1 Functional Meter Test ...................................................................................................................................... 48
2.4.2 EMC Test ........................................................................................................................................................ 50
2.5 Sensors and Sensor Placement .......................................................................................................................... 50
2.5.1 Self-Heating .................................................................................................................................................... 51
2.5.2 Placement of Sensors (ANSI) ......................................................................................................................... 51
2.5.3 Placement of Sensors (IEC) ............................................................................................................................ 51
2.5.4 Other Techniques for Avoiding Magnetic Crosstalk......................................................................................... 52
3 HARDWARE DESCRIPTION ................................................................................................................................. 55
3.1 71M6543 REV 4.0 Demo Board Description: Jumpers, Switches and Test Points ......................................... 55
3.2 71M6543 REV 5.0 Demo Board Description ....................................................................................................... 59
3.3 Board Hardware Specifications .......................................................................................................................... 60
4 APPENDIX ............................................................................................................................................................. 61
4.1 71M6543 Demo Board Rev 4.0 Electrical Schematic ......................................................................................... 62
4.2 71M6543 Demo Board Rev 5.0 Electrical Schematic ......................................................................................... 66
4.3 Comments on Schematics ................................................................................................................................... 70
4.3.1 General ........................................................................................................................................................... 70
4.3.2 Using Ferrites in the Shunt Sensor Inputs ....................................................................................................... 70
4.4 71M6543 Demo Board REV 4.0 Bill of Material .................................................................................................. 71
4.5 71M6543 Demo Board REV 5.0 Bill of Material .................................................................................................. 73
4.6 71M6543 REV 4.0 Demo Board PCB Layout ....................................................................................................... 75
4.7 71M6543 REV 5.0 Demo Board PCB Layout ....................................................................................................... 79
4.8 Debug Board Bill of Material ............................................................................................................................... 83
4.9 Debug Board Schematics .................................................................................................................................... 84
4.10 Optional Debug Board PCB Layout ................................................................................................................. 85
4.11 71M6543 Pin-Out Information .......................................................................................................................... 88
4.12 Revision History ............................................................................................................................................... 91
List of Figures
Figure 1-1: Teridian 71M6543 REV4.0 Demo Board with Debug Board: Basic Connections .............................................. 9
Figure 1-2: HyperTerminal Sample Window with Disconnect Button (Arrow) ................................................................... 12
Figure 1-3: Port Speed and Handshake Setup (left) and Port Bit setup (right) .................................................................. 12
Figure 1-4: Typical Calibration Macro File ......................................................................................................................... 21
Figure 1-5: Emulator Window Showing Reset and Erase Buttons (see Arrows) ............................................................... 22
Figure 1-6: Emulator Window Showing Erased Flash Memory and File Load Menu ......................................................... 23
Figure 1-7: Worksheet from Calibration Spreadsheets REV 6.0 ....................................................................................... 32
Figure 2-1: Watt Meter with Gain and Phase Errors. ......................................................................................................... 35
Figure 2-2: Phase Angle Definitions .................................................................................................................................. 39
Figure 2-3: Calibration Spreadsheet for Three Measurements ......................................................................................... 41
Figure 2-4: Calibration Spreadsheet for Five Measurements ............................................................................................ 42
Figure 2-5: Non-Linearity Caused by Quantification Noise ............................................................................................... 42
Figure 2-6: Wh Registration Error with VREF Compensation ........................................................................................... 47
Figure 2-7: Wh Registration Error with Combined Compensation ..................................................................................... 48
Figure 2-8: Meter with Calibration System ........................................................................................................................ 49
Figure 2-9: Calibration System Screen ............................................................................................................................. 49
Figure 2-10: Wh Load Lines at Room Temperature with 150 µΩ Shunts .......................................................................... 50
Figure 2-11: VARh Load Lines at Room Temperature with 150 µΩ Shunts ...................................................................... 50
Figure 2-12: Typical Sensor Arrangement (left), Alternative Arrangement (right) ............................................................. 52
Figure 2-13: Swiveled Sensor Arrangement ..................................................................................................................... 52
Figure 2-17: Loop Formed by Shunt and Sensor Wire ...................................................................................................... 53
Figure 2-18: Shunt with Compensation Loop .................................................................................................................... 53
Figure 2-19: Shunt with Center Drill Holes ........................................................................................................................ 53
Figure 3-1: 71M6543 REV 4.0 Demo Board - Board Description ...................................................................................... 58
71M6543 Demo Board User’s Manual
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Figure 3-2: 71M6543 REV 5.0 Demo Board – Top View ................................................................................................... 59
Figure 4-1: Teridian 71M6543 REV 4.0 Demo Board: Electrical Schematic 1/4 ............................................................... 62
Figure 4-2: Teridian 71M6543 REV 4.0 Demo Board: Electrical Schematic 2/4 ............................................................... 63
Figure 4-3: Teridian 71M6543 REV 4.0 Demo Board: Electrical Schematic 3/4 ............................................................... 64
Figure 4-4: Teridian 71M6543 REV 4.0 Demo Board: Electrical Schematic 4/4 ............................................................... 65
Figure 4-5: Teridian 71M6543 REV 5.0 Demo Board: Electrical Schematic 1/4 ............................................................... 66
Figure 4-6: Teridian 71M6543 REV 5.0 Demo Board: Electrical Schematic 2/4 ............................................................... 67
Figure 4-7: Teridian 71M6543 REV 5.0 Demo Board: Electrical Schematic 3/4 ............................................................... 68
Figure 4-8: Teridian 71M6543 REV 5.0 Demo Board: Electrical Schematic 4/4 ............................................................... 69
Figure 4-9: Input Circuit with Ferrites ................................................................................................................................ 70
Figure 4-10: Teridian 71M6543 REV 4.0 Demo Board: Top View ..................................................................................... 75
Figure 4-11: Teridian 71M6543 REV 4.0 Demo Board: Top Copper ................................................................................. 76
Figure 4-12: Teridian 71M6543 REV 4.0 Demo Board: Bottom View ................................................................................ 77
Figure 4-13: Teridian 71M6543 REV 4.0 Demo Board: Bottom Copper ............................................................................ 78
Figure 4-14: Teridian 71M6543 REV 5.0 Demo Board: Top View ..................................................................................... 79
Figure 4-15: Teridian 71M6543 REV 5.0 Demo Board: Top Copper ................................................................................. 80
Figure 4-16: Teridian 71M6543 REV 5.0 Demo Board: Bottom View ................................................................................ 81
Figure 4-17: Teridian 71M6543 REV 5.0 Demo Board: Bottom Copper ............................................................................ 82
Figure 4-18: Debug Board: Electrical Schematic............................................................................................................... 84
Figure 4-19: Debug Board: Top View ................................................................................................................................ 85
Figure 4-20: Debug Board: Bottom View ........................................................................................................................... 85
Figure 4-21: Debug Board: Top Signal Layer .................................................................................................................... 86
Figure 4-22: Debug Board: Middle Layer 1 (Ground Plane) .............................................................................................. 86
Figure 4-23: Debug Board: Middle Layer 2 (Supply Plane) ............................................................................................... 87
Figure 4-24: Debug Board: Bottom Trace Layer ............................................................................................................... 87
Figure 4-25: 71M6543, LQFP100: Pin-out (top view) ........................................................................................................ 90
List of Tables
Table 1-1: Jumper Settings on Debug Board .................................................................................................................... 10
Table 1-2: Straight Cable Connections ............................................................................................................................. 10
Table 1-3: Null-modem Cable Connections ...................................................................................................................... 10
Table 1-4: CE RAM Locations for Calibration Constants .................................................................................................. 21
Table 1-5: Flash Programming Interface Signals .............................................................................................................. 23
Table 1-6: Demo Code Versions ....................................................................................................................................... 24
Table 1-7: MPU XRAM Locations ..................................................................................................................................... 25
Table 1-8: Bits in the MPU Status Word ............................................................................................................................ 30
Table 1-9: CE Registers and Associated LSB Values ....................................................................................................... 31
Table 1-10: IMAX for Various Shunt Resistance Values and Remote Sensor Types ........................................................ 31
Table 1-11: Identification of 71M6x0x Remote Sensor Types ........................................................................................... 33
Table 2-1: Temperature-Related Error Sources ................................................................................................................ 44
Table 2-2: MPU Registers for Temperature-Compensation .............................................................................................. 45
Table 2-3: Temperature-Related Error Sources ................................................................................................................ 46
Table 3-1: 71M6543 REV 4.0 Demo Board Description .................................................................................................... 55
Table 4-1: 71M6543 REV 4.0 Demo Board: Bill of Material (1/2) ...................................................................................... 71
Table 4-2: 71M6543 REV 4.0 Demo Board: Bill of Material (2/2) ...................................................................................... 72
Table 4-3: 71M6543 REV 5.0 Demo Board: Bill of Material (1/3) ...................................................................................... 73
Table 4-4: 71M6543 REV 5.0 Demo Board: Bill of Material (2/3) ...................................................................................... 74
Table 4-5: Debug Board: Bill of Material ........................................................................................................................... 83
Table 4-6: 71M6543 Pin Description Table 1/3 ................................................................................................................. 88
Table 4-7: 71M6543 Pin Description Table 2/3 ................................................................................................................. 88
Table 4-8: 71M6543 Pin Description Table 3/3 ................................................................................................................. 89
71M6543 Demo Board User’s Manual
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71M6543 Demo Board User’s Manual
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1 GETTING STARTED
1.1 GENERAL
The Teridian™ 71M6543 REV 4.0 and REV 5.0 Demo Boards are demonstration boards for evaluating the
71M6543F device for polyphase electronic power metering applications in conjunction with the Remote Sensor
Interface or CT sensors. The Demo Boards allow the evaluation of the 71M6543F energy meter chip for meas-
urement accuracy and overall system use.
The 71M6543 REV 4.0 Demo Board incorporates a 71M6543F integrated circuit, three 71M6103 or 71M6203
Remote Interface ICs, peripheral circuitry such as a serial EEPROM, emulator port, and on-board power supply,
as well as a USB interface for serial communication with a PC.
The 71M6543 REV 5.0 Demo Board is optimized and prepared for the connection of external CTs and is other-
wise identical to the REV 4.0 Demo Board.
All Demo Boards are pre-programmed with a Demo Program (Demo Code) in the FLASH memory of the
71M6543F IC. This embedded application is developed to exercise all low-level function calls to directly man-
age the peripherals, flash programming, and CPU (clock, timing, power savings, etc.).
The 71M6543F IC on the REV 4.0 Demo Board is pre-programmed and pre-calibrated for the 50 µΩ or 120 µΩ
shunts shipped with the board. The Demo Board may also be used for operation with a CT after hardware modi-
fications that can be performed by the user. This configuration will require a different version of the Demo Code
and different settings. It should be noted that the 71M6543 performs better with CTs when used with the
71M6543 REV 5.0 Demo Board.
1.2 SAFETY AND ESD NOTES
Connecting live voltages to the demo board system will result in potentially hazardous voltages on the demo
board.
THE DEMO SYSTEM IS ESD SENSITIVE! ESD PRECAUTIONS SHOULD BE TAKEN
WHEN HANDLING THE DEMO BOARD!
EXTREME CAUTION SHOULD BE TAKEN WHEN HANDLING THE DEMO BOARD
ONCE IT IS CONNECTED TO LIVE VOLTAGES! BOARD GROUND IS CLOSE TO LIVE
VOLTAGE!
1
Teridian is a trademark of Maxim Integrated Products, Inc.
71M6543 Demo Board User’s Manual
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1.3 DEMO KIT CONTENTS
• 71M6543 Demo Board REV 4.0 with three 71M6203 or 71M6103 ICs and one 71M6543F IC with pre-
loaded demo program, or 71M6543 Demo Board REV 5.0 with inputs configured for CTs.
• 5VDC/1,000mA universal wall transformer with 2.5mm plug (Switchcraft 712A compatible)
• USB Interface Module (USB/Serial Adapter)
• USB cable
• ANSI base with three 50 μΩ shunt resistors, Oswell P/N EBSB20050H-92-19-73-6.4-V1 (optional, for
ANSI kits only)
• Three 120 μΩ shunt resistors, Oswell P/N EBSA15120-32-14.8-21-6.2-V1 (optional, for IEC kits)
1.4 DEMO BOARD VERSIONS
The following versions of the Demo Board are or have been available:
• 71M6543 Demo Board Rev 1.0 (CTs only) - discontinued
• 71M6543 Demo Board Rev 2.0 (CTs or 71M6103 Remote Sensor Interface ICs on daughter boards) -
discontinued
• 71M6543 Demo Board Rev 3.0 (71M6103 Remote Sensor Interface ICs) - discontinued
• 71M6543 Demo Board Rev 4.0 (71M6103 Remote Sensor Interface ICs)
• 71M6543 Demo Board Rev 5.0 (CTs or 71M6103 Remote Sensor Interface ICs
This manual applies to 71M6543 Rev 4.0 and Rev 5.0 only. For the earlier Demo Board revisions please see
their respective manuals.
1.5 COMPATIBILITY
This manual applies to the following hardware and software revisions:
• 71M6543F IC revision B02.
• Demo Code revision 5.4F or later
• 71M6543 Demo Board Rev 4.0 or Rev. 5.0
1.6 SUGGESTED EQUIPMENT NOT INCLUDED
For functional demonstration:
PC with Microsoft Windows versions Windows XP, ME, or 2000, equipped with RS-232 port (COM port) via
DB9 connector
For software development (MPU code):
Signum ICE (In Circuit Emulator): ADM-51
www.signum.com
Signum WEMU51 version 3.11.09 or later should be used. Using a USB isolator between PC and the Signum
ADM-51 is strongly recommended
Keil 8051 “C” Compiler kit: CA51
www.keil.com/c51/ca51kit.htm, www.keil.com/product/sales.htm
Windows and Windows XP are registered trademarks of Microsoft Corp.
71M6543 Demo Board User’s Manual
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1.7 DEMO BOARD TEST SETUP
Figure 1-1 shows the basic connections of the Demo Board REV 4.0 plus optional Debug Board with the exter-
nal equipment. The PC should be connected via the USB Interface (CN1). Communication can also be estab-
lished via the optional Debug Board, but this board is not part of the Demo Kit.
For stand-alone testing (without AC voltage) the Demo Board maybe powered via the 5.0 VDC input (J20). The
optional Debug Board must be powered with its own 5 VDC power supply.
Figure 1-1: Teridian 71M6543 REV4.0 Demo Board with Debug Board: Basic Connections
The Demo Board contains all circuits necessary for operation as a meter, including display, calibration LEDs,
and internal power supply. The optional Debug Board uses a separate power supply, and is optically isolated
from the Demo Board. It interfaces to a PC through a 9 pin serial port connector.
It is recommended to set up the demo board with no live AC voltage connected, and to
connect live AC voltages only after the user is familiar with the demo system.
All input signals are referenced to the V3P3A (3.3V power supply to the chip).
DEMONSTRATION METER
IA
IB
IC
VC
VB
NEUTRAL
IAP
IBP
ICP
V3P3A
VC
VB
VA
VA
GND
V3P3
GND
3.3V DC
Input
EEPROM
ICE Connector
SEGDIO52
SEGDIO10
TX
RX
DB9
to PC
COM Port
6543
Single Chip Meter
TMUXOUT
TMUX2OUT
3.3V or 5V
LCD
SDCK
SDATA
IDP
INEUTRAL
External Shunt
Resistors
IAN
IBN
ICN
V3P3SYS
Wh
VARh
SEGDIO0/WPULSE
SEGDIO1/VPULSE
PULSE OUTPUTS
SEGDIO7/YPULSE
SEGDIO6/XPULSE
V3P3SYS
V3P3D
VBAT
Battery 2
(optional)
J13
PB
On-board components
powered by V3P3D
OPTO
OPTO
OPTO
OPTO
OPTO
5V DC
V5_DBG
GND_DBG
V5_DBG
V5_DBG
RS-232
INTERFACE
GND_DBG
V5_DBG
OPTO
OPTO
FPGA
2/4/2011
V5_NI
CE HEARTBEAT (1Hz)
MPU HEARTBEAT (5Hz)
DEBUG BOARD (OPTIONAL)
RTM INTERFACE
JP21
J21
4
15, 16
13, 14
6
6
8
12
10
3
1
2
5, 7,
9, 11
GND
V3P3SYS
JP6
IDN
J1
PULSE A
PULSE B
SMPS
J5
68 Pin
Connector
VBAT_RTC
Battery 1
(optional)
RESET
JP56
J12
J20
SPI Connector
J14
J19
JP5
CN1
Isolated RS-
232 transceiver
RESET
PB
USB
Interface
71M6103 or 71M6203
Remote Sensor
Interfaces and
isolation transformers
SW4
SEGDIO53
JP53
To PC
71M6543 Demo Board User’s Manual
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1.7.1 POWER SUPPLY SETUP
There are several choices for the meter power supply:
o Internal (using the AC line voltage). The internal power supply is only suitable when the voltage ex-
ceeds 100V RMS. To enable the internal supply, a jumper needs to be installed across JP6 on the top
of the board.
o External 5.0 VDC connector (JP20) on the Demo Board.
1.7.2 CABLES FOR SERIAL COMMUNICATION
It is recommended to use the USB connection to communicate with the Demo Code. The optional Debug
Board is not normally shipped with the Demo Kit and requires a serial port (DB9) on the PC along with a sepa-
rate power supply.
1.7.2.1 USB Connection
A standard USB cable can be used to connect the Demo Board to a PC running HyperTerminal or a similar se-
rial interface program. A suitable driver, e.g. the FTDI CDM Driver Package, must be installed on the PC to en-
able the USB port to be mapped as a virtual COM port. The driver can be found on the FTDI web site
(http://www.ftdichip.com/Drivers/D2XX.htm).
See Table 3-1 for correct placement of jumper JP5 depending on whether the USB connection or the serial
connection via the optional Debug Board is used.
1.7.2.2 Serial Connection (Optional)
For connection of the DB9 serial port of the Debug Board to a PC serial port (COM port), either a straight or a
so-called “null-modem” cable may be used. JP1 and JP2 are plugged in for the straight cable, and JP3/JP4 are
empty. The jumper configuration is reversed for the null-modem cable, as shown in Table 1-1.
Cable Configura-
tion Mode
Jumpers on Debug Board
JP1
JP2
JP3
JP4
Straight Cable
Default
Installed Installed -- --
Null-Modem Cable Alternative -- -- Installed Installed
Table 1-1: Jumper Settings on Debug Board
JP1 through JP4 can also be used to alter the connection when the PC is not configured as a DCE device. Ta-
ble 1-2 shows the connections necessary for the straight DB9 cable and the pin definitions.
PC Pin
Function
Demo Board Pin
2 TX 2
3 RX 3
5 Signal Ground 5
Table 1-2: Straight Cable Connections
Table 1-3 shows the connections necessary for the null-modem DB9 cable and the pin definitions.
PC Pin Function Demo Board Pin
2 TX 3
3 RX 2
5 Signal Ground 5
Table 1-3: Null-modem Cable Connections
See Table 3-1 for correct placement of jumper JP5 on the Demo Board depending on whether the USB connec-
tion or the serial connection via the Debug Board is used.
71M6543 Demo Board User’s Manual
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1.7.3 CHECKING OPERATION
A few seconds after power up, the LCD display on the Demo Board should display a brief greeting in the top
row and the demo code revision in the bottom row:
H
E
L
L
O
5.
4
F
The “HELLO” message should be followed by the display of accumulated energy:
0.
0
0
Wh SYS
0
3
The “SYS” symbol will be blinking, indicating activity of the MPU inside the 71M6543.
In general, the fields of the LCD are used as shown below:
Measured value
Unit
Command number
(Phase)
1.7.4 SERIAL CONNECTION SETUP
After connecting the USB cable from the Demo Board to the PC, or after connecting the serial cable from the
optional Debug Board to the PC, start the HyperTerminal application and create a session using the following
parameters:
Port Speed: 9600 bd
Data Bits: 8
Parity: None
Stop Bits: 1
Flow Control: XON/XOFF
When using the USB connection, you may have to define a new port in HyperTerminal after selecting File
Properties and then clicking on the “Connect Using“ dialog box. If the USB-to-serial driver is installed (see sec-
tion 1.7.2.1) a port with a number not corresponding to an actual serial port, e.g. COM27, will appear in the dia-
log box. This port should be selected for the USB connection.
HyperTerminal can be found by selecting Programs Accessories Communications from the Windows start
menu. The connection parameters are configured by selecting File Properties and then by pressing the Con-
figure button. Port speed and flow control are configured under the General tab (Figure 1-3, left), bit settings are
configured by pressing the Configure button (Figure 1-3, right), as shown below. A setup file (file name “Demo
Board Connection.ht”) for HyperTerminal that can be loaded with File Open is also provided with the tools
and utilities.
In Windows 7 , HyperTerminal is not available, but can be installed from various resources on the Internet.
Port parameters can only be adjusted when the connection is not active. The disconnect
button, as shown in Figure 1-2 must be clicked in order to disconnect the port.
71M6543 Demo Board User’s Manual
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Figure 1-2: HyperTerminal Sample Window with Disconnect Button (Arrow)
Figure 1-3: Port Setup (left) and Port Speed and Handshake Setup (right)
Once, the connection to the demo board is established, press <CR> and the command prompt, >, should ap-
pear. Type >? to see the Demo Code help menu. Type >i to verify the demo code revision.
1.8 USING THE DEMO BOARD
The 71M6543 Demo Board is a ready-to-use meter prepared for use with external shunt resistors.
Demo Code versions for polyphase operation (EQU 5) are available on the Maxim web site (www.maxim-
ic.com) and the 71M6543F is pre-programmed with Demo Code that supports polyphase metering.
Using the Demo Board involves communicating with the Demo Code via the command line interface (CLI). The
CLI allows all sorts of manipulations to the metering parameters, access to the EEPROM, selection of the dis-
played parameters, changing calibration factors and many more operations.
Before evaluating the 71M6543F on the Demo Board, users should get familiar with the commands and re-
sponses of the CLI. A complete description of the CLI is provided in section 1.8.1.
71M6543 Demo Board User’s Manual
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1.8.1 SERIAL COMMAND LANGUAGE
The Demo Code residing in the flash memory of the 71M6543F provides a convenient way of examining and
modifying key meter parameters via its command line interface (CLI).
The tables in this chapter describe the commands in detail.
Commands for CE Data Access:
] CE DATA ACCESS Comment
Description: Allows user to read from and write to CE data space.
Usage: ] [Starting CE Data Address] [option]…[option]
Command
combinations:
]A??? Read consecutive 16-bit words in Decimal, starting at ad-
dress A
]A$$$ Read consecutive 16-bit words in Hex, starting at address A
]A=n=n Write consecutive memory values, starting at address A
]U Update default version of CE Data in flash memory
Example: ]40$$$ Reads CE data words 0x40, 0x41 and 0x42.
]7E=12345678=9876ABCD Writes two words starting @ 0x7E
All CE data words are in 4-byte (32-bit) format. Typing ]A? will access the 32-bit word located at the byte ad-
dress 0x0000 + 4 * A = 0x1028.
Commands for MPU/XDATA Access:
) MPU DATA ACCESS Comment
Description: Allows user to read from and write to MPU data space.
Usage: ) [Starting MPU Data Address] [option]…[option]
Command
combinations:
)A??? Read three consecutive 32-bit words in Decimal, starting at
address A
)A$$$ Read three consecutive 32-bit words in Hex, starting at ad-
dress A
)A=n=m Write the values n and m to two consecutive addresses start-
ing at address A
?) Display useful RAM addresses.
Example: )08$$$$ Reads data words 0x08, 0x0C, 0x10, 0x14
)04=12345678=9876ABCD Writes two words starting @ 0x04
MPU or XDATA space is the address range for the MPU XRAM (0x0000 to 0xFFF). All MPU data words are in 4-byte (32-bit)
format. Typing ]A? will access the 32-bit word located at the byte address 4 * A = 0x28. The energy accumulation registers of
the Demo Code can be accessed by typing two Dollar signs (“$$”), typing question marks will display negative decimal values
if the most significant bit is set.
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Commands for DIO RAM (Configuration RAM) and SFR Control:
R DIO AND SFR CONTROL Comment
Description: Allows the user to read from and write to DIO RAM and special function registers (SFRs).
Usage: R [option] [register] … [option]
Command
combinations: RIx… Select I/O RAM location x (0x2000 offset is automatically
added)
Rx… Select internal SFR at address x
Ra???... Read consecutive SFR registers in Decimal, starting at ad-
dress a
Ra$$$... Read consecutive registers in Hex, starting at address a
Ra=n=m… Set values of consecutive registers to n and m starting at
address a
Example: RI2$$$ Read DIO RAM registers 2, 3, and 4 in Hex.
The SFRs (special function registers) are located in internal RAM of the 80515 core, starting at address 0x80.
Commands for EEPROM Control:
EE EEPROM CONTROL Comment
Description: Allows user to enable read from and write to EEPROM.
Usage: EE [option] [arguments]
Command
combinations:
EECn EEPROM Access (1 Enable, 0 Disable)
EERa.b Read EEPROM at address 'a' for 'b' bytes.
EESabc..xyz Write characters to buffer (sets Write length)
EETa Transmit buffer to EEPROM at address 'a'.
EEWa.b...z Write values to buffer
CLS Saves calibration to EEPROM
Example: EEShello
EET$0210
Writes 'hello' to buffer, then transmits buffer to EEPROM start-
ing at address 0x210.
Due to buffer size restrictions, the maximum number of bytes handled by the EEPROM command is 0x40.
Commands for Flash Memory Control:
F FLASH CONTROL Comment
Description: Allows user to enable read from and write to Flash memory.
Usage: F [option] [arguments]
Command
combinations:
FRa.b Read Flash at address 'a' for 'b' bytes.
FSabc..xyz Write characters to buffer (sets Write length)
FTa Transmit buffer to Flash memory at address 'a'.
FWa.b...z Write string of bytes to buffer
Example: FShello
FT$FE10
Writes 'hello' to buffer, then transmits buffer to EEPROM start-
ing at address 0xFE10.
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Auxiliary Commands:
Typing a comma (“,”) repeats the command issued from the previous command line. This is very helpful when
examining the value at a certain address over time, such as the CE DRAM address for the temperature (0x40).
The slash (“/”) is useful to separate comments from commands when sending macro text files via the serial in-
terface. All characters in a line after the slash are ignored.
Commands controlling the CE, TMUX and the RTM:
C COMPUTE ENGINE,
MEMORY, AND CALIBRA-
TION CONTROL
Comment
Description: Allows the user to enable and configure the compute engine, store and recall configurations, and
initiate calibration.
Usage: C [option] [argument]
Command
combinations: CEn Compute Engine Enable (1 Enable,
0 Disable)
CTn.m Selects the signal for the TMUX output pins (n = 1 for
TMUXOUT, n = 2 for TMUX2OUT). M is interpreted as a hex
number.
CREn RTM output control (1 Enable, 0 Disable)
CRSa.b.c.d Selects CE addresses for RTM output
CLS Stores calibration and other settings to EEPROM.
CLR Restores calibration and other settings from EEPROM.
CLD Restores calibration and other settings to defaults.
CLB Start auto-calibration based on voltage (MPU address 0x0C,
current (MPU 0x0D), and duration (MPU 0x0E) in seconds.
CLC Apply machine-readable calibration control (Intel Hex-
Records).
CPA Start the accumulating periodic pulse counters.
CPC Clear the pulse counters
CPDn Activate pulse counters for n seconds
Example: CE0 Disables CE, (“SYS will stop blinking on the LCD).
CT1.12 Selects the VBIAS signal for the TMUXOUT pin
Commands for Identification and Information:
I INFORMATION MESSAGES Comment
Description: Allows the user to read information messages.
Usage: I Sends complete demo code version information on serial inter-
face.
M0 Displays meter ID on LCD.
The I command is mainly used to identify the revisions of Demo Code and the contained CE code.
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Commands for Battery Mode Control and Battery Test:
B INFORMATION MESSAGES Comment
Description: Allows the user to control battery modes and to test the battery.
Usage: BL Enters LCD mode when in brownout mode (B> prompt).
BS Enters sleep mode when in brownout mode (B> prompt).
BT Starts a battery test – when in mission mode (> prompt).
BWSn Set wake timer to n seconds for automatic return to brownout
mode.
BWMn Set wake timer to n minutes for automatic return to brownout
mode.
Commands for Controlling the RTC:
RT REAL TIME CLOCK CON-
TROL
Comment
Description: Allows the user to read and set the real time clock.
Usage: RT [option] [value] … [value]
Command
combinations: RTDy.m.d.w: Day of week (Year, month, day, weekday [1 = Sunday]). If the weekday is
omitted it is set automatically.
RTR Read Real Time Clock.
RTTh.m.s Time of day: (hr, min, sec).
RTAs.t Real Time Adjust: (start, trim). Allows trimming of the RTC.
If s > 0, the speed of the clock will be adjusted by ‘t’ parts per
billion (PPB). If the CE is on, the value entered with 't' will be
changing with temperature, based on Y_CAL, Y_CALC and
Y_CALC2.
> Access look-up table for RTC compensation.
Example: RTD05.03.17.5 Programs the RTC to Thursday, 3/17/2005
RTA1.+1234 Speeds up the RTC by 1234 PPB.
>0???? Read the first four bytes in the look-up table.
The “Military Time Format” is used for the RTC, i.e. 15:00 is 3:00 PM.
Commands for Accessing the Trim Control Registers:
T TRIM CONTROL Comment
Description: Allows user to read trim and fuse values.
Usage: T [option]
Command
combinations:
T4 Read fuse 4 (TRIMM).
T5 Read fuse 5 (TRIMBGA)
T6 Read fuse 6 (TRIMBGB).
Example: T4 Reads the TRIMM fuse.
These commands are only accessible for the 71M6543H (0.1%) parts. When used on a 71M6543F (0.5%) part,
the results will be displayed as zero.
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Reset Commands:
W RESET Comment
Description: Watchdog control
Usage: W Halts the Demo Code program, thus suppressing the trigger-
ing of the hardware watchdog timer. This will cause a reset, if
the watchdog timer is enabled.
Commands for the 71M6x0x Remote Sensor Interface:
6 71M6x0x Interface Comment
Description: Commands for control of the Re-
mote Sensor Interface IC.
Usage: 6En Remote sensor Enable (1 Enable, 0 Disable)
6Ra.b Read Remote Sensor IC number a with command b.
6Ca.b Write command b to Remote Sensor IC number a.
6Ta.b Send command b to Remote Sensor IC number a in a loop
forever.
6T Send temp command to 6000 number 2 in a loop forever.
6R1.20 Reads the temperature from Remote Sensor IC number 1.
See section 1.10.7 for information on how to interpret the
temperature data.
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Commands for Controlling the Metering Values Shown on the LCD Display:
Step
Text or Nu-
merical Dis-
play
CLI
command Displayed Parameter(s)
0 10000
00 M0 Meter ID
1 24.5 °C
01 M1 Temperature difference from calibration temperature. Displayed in
0.1°C
2 59.9
02 M2 Frequency at the VA_IN input [Hz]
3 3.27 Wh
03 M3 Accumulated imported real energy [Wh]. The default display setting
after power-up or reset.
4
1.04 Wh
04
M4 Accumulated exported real energy [Wh].
5
2.21 VARh
05
M5 Accumulated reactive energy [VARh].
6
0.95 VARh
06
M6 Accumulated exported reactive energy [VARh].
7
4.11 VAh
07
M7 Accumulated apparent energy [VAh].
8
0.7 h
08
M8 Elapsed time since last reset or power up.
9
01:43:59
09
M9 Time of day (hh.mm.ss)
10
01.01.01
10
M10 Date (yy.mm.dd)
11
0.62
11
1
M11.P Power factor (P = phase)
12 0 M12 Not used in the 71M6543
13
120
13
M13 Zero crossings of the mains voltage
14
48
14
M14 Duration of sag or neutral current [s]
15
29.98 A
29.91 A
30.02 A
M15 RMS current (P = phase). “M15.4” displays the neutral current.
16
240.27 V
239.43 V
240.04 V
M16 RMS voltage
17
3.34 V
17
M17 Battery voltage
18
241.34 W
240.92 W
241.01 W
M18 Momentary power in W (P = phase)
19
50400 W
19
M19 Demand
20
88.88.88
88.88.88
88.88.88
M20 LCD Test
Displays for total consumption wrap around at 999.999Wh (or VARh, VAh) due to the limited number of avail-
able display digits. Internal registers (counters) of the Demo Code are 64 bits wide and do not wrap around.
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1.8.2 USING THE DEMO BOARD FOR ENERGY MEASUREMENTS
The 71M6543 Demo Board was designed for use with shunt resistors connected via the Remote Sensor Inter-
faces and it is shipped in this configuration.
The Demo Board may immediately be used with 50 µΩ shunt resistors (ANSI version) or 120 µΩ shunt resistors
(IEC version). It is programmed for a kh factor of 3.2 (see Section 1.8.4 for adjusting the Demo Board for
shunts with different resistance).
Once, voltage is applied and load current is flowing, the red LED D5 will flash each time an energy sum of 3.2
Wh is collected. The LCD display will show the accumulated energy in Wh when set to display mode 3 (com-
mand >M3 via the serial interface).
Similarly, the red LED D6 will flash each time an energy sum of 3.2 VARh is collected. The LCD display will
show the accumulated energy in VARh when set to display mode 5 (command >M5 via the serial interface).
1.8.3 ADJUSTING THE KH FACTOR FOR THE DEMO BOARD
The 71M6543 Demo Board is shipped with a pre-programmed scaling factor Kh of 3.2, i.e. 3.2 Wh per pulse. In
order to be used with a calibrated load or a meter calibration system, the board should be connected to the AC
power source using the spade terminals on the bottom of the board. On the revision REV 4.0 of the Demo
Board, the shunt resistor wires are terminated directly to the dual-pin headers J22, J23, and J24 on the board.
The Kh value can be derived by reading the values for IMAX and VMAX (i.e. the RMS current and voltage val-
ues that correspond to the 250mV maximum input signal to the IC), and inserting them in the following equation
for Kh:
Kh = 54.5793*VMAX*IMAX / (SUM_SAMPS*WRATE*X),
See the explanation in section 1.10.5 for an exact definition of the constants and variables involved in the equa-
tion above.
1.8.4 ADJUSTING THE DEMO BOARDS TO DIFFERENT SHUNT RESISTORS
The Demo Board REV 4.0 is prepared for use with 120 µΩ or 50 µOhm (ANSI option) shunt resistors in all cur-
rent channels. A certain current flowing through the 120 µΩ shunt resistors will result in the maximum voltage
drop at the ADC of the 71M6103 Remote Sensor ICs. This current is defined as IMAX and can be adjusted at
MPU location 0x03 (see section 1.10.3).
IMAX will need to be changed when different values are used for the shunt resistor(s) which will require that
WRATE has to be updated as shown in section 1.10.5.
The scaling of the neutral current measurement is controlled by the i_max2 variable at MPU location 0x01C.
1.8.5 USING THE PRE-AMPLIFIER
In its default setting, the 71M6543F applies a gain of 1 to the current input for the neutral current inputs
(IAP/IAN pins). This gain is controlled with the PRE_E bit in I/O RAM (see the Data Sheet). The command line
interface (RI command) can be used to set or reset this bit. It is recommended to maintain the gain of setting of
1 (RI2704=0x90).
1.8.6 USING CURRENT TRANSFORMERS (CTS)
All phases of the 71M6543 REV 5.0 Demo Board are equipped with connectors for external CTs. CTs should be
connected to the headers J5, J7, and J10. A burden resistor of 1.7 Ω is installed at the R26, R27, and R31 (and
corresponding resistors for phases B and C) locations. With a 2000:1 ratio CT, the maximum current will be 208
A.
For the CT configuration, a shunt resistor of 50 µΩ should be installed to measure the neutral current. Different
values can be accommodated by changing the value of i_max2 at MPU location 0x1C (see section 1.10.3).
Note: The CT configuration requires a different version of the Demo Code than is used for the shunt
configuration.
1.8.7 ADJUSTING THE DEMO BOARDS TO DIFFERENT VOLTAGE DIVIDERS
The 71M6543 Demo Board comes equipped with its own network of resistor dividers for voltage measurement
mounted on the PCB. The resistor values (for the 71M6543 REV 2.0 Demo Board) are 2.5477MΩ (R66, R64,
R47, R39 combined) and 750Ω (R32, R52, R72), resulting in a ratio of 1:3,393.933. This means that VMAX
equals 176.78mV*3,393.933 = 600V. A large value for VMAX has been selected in order to have headroom for
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over-voltages. This choice need not be of concern, since the ADC in the 71M6543F has enough resolution,
even when operating at 120 Vrms or 240 Vrms.
If a different set of voltage dividers or an external voltage transformer (potential transformer) is to be used,
scaling techniques should be used.
In the following example we assume that the line voltage is not applied to the resistor divider for VA formed by
R66, R64, R47, R39, and R32, but to a voltage transformer with a ratio N of 20:1, followed by a simple resistor
divider. We also assume that we want to maintain the value for VMAX at 600V to provide headroom for large
voltage excursions.
When applying VMAX at the primary side of the transformer, the secondary voltage Vs is:
Vs = VMAX / N
Vs is scaled by the resistor divider ratio RR. When the input voltage to the voltage channel of the 71M6543 is the
desired 177mV, Vs is then given by:
Vs = RR * 176.8 mV
Resolving for RR, we get:
RR = (VMAX / N) / 176.8 mV = (600V / 30) / 176.8 mV = 170.45
This divider ratio can be implemented, for example, with a combination of one 16.95 kΩ and one 100 Ω resistor.
If potential transformers (PTs) are used instead of resistor dividers, phase shifts will be introduced that will re-
quire negative phase angle compensation. Teridian Demo Code accepts negative calibration factors for phase.
1.9 CALIBRATION PARAMETERS
1.9.1 GENERAL CALIBRATION PROCEDURE
Any calibration method can be used with the 71M6543F ICs. This Demo Board User’s Manual presents calibra-
tion methods with three or five measurements as recommended methods, because they work with most manual
calibration systems based on counting "pulses" (emitted by LEDs on the meter).
Naturally, a meter in mass production will be equipped with special calibration code offering capabilities beyond
those of the 71M6543 Demo Code. It is basically possible to calibrate using voltage and current readings, with
or without pulses involved. For this purpose, the MPU Demo Code should be modified to display averaged volt-
age and current values (as opposed to momentary values). Also, automated calibration equipment can com-
municate with the Demo Boards via the serial interface and extract voltage and current readings. This is possi-
ble even with the unmodified Demo Code.
Complete calibration procedures are given in section 2.2 of this manual.
Regardless of the calibration procedure used, parameters (calibration factors) will result that will have to be ap-
plied to the 71M6543F IC in order to make the chip apply the modified gains and phase shifts necessary for ac-
curate operation. Table 1-4 shows the names of the calibration factors, their function, and their location in the
CE RAM.
Again, the command line interface can be used to store the calibration factors in their respective CE RAM ad-
dresses. For example, the command
>]10=+16302
stores the decimal value 16302 in the CE RAM location controlling the gain of the current channel (CAL_IA).
The command
>]11=4005
stores the hexadecimal value 0x4005 (decimal 16389) in the CE RAM location controlling the gain of the volt-
age channel (CAL_VA).
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Table 1-4: CE RAM Locations for Calibration Constants
Coefficient
CE Ad-
dress
(hex)
Description
CAL_VA
CAL_VB
CAL_VC
0x11
0x14
0x17
Adjusts the gain of the voltage channels. +16384 is the typical value. The
gain is directly proportional to the CAL parameter. Allowed range is 0 to
32767. If the gain is 1% slow, CAL should be increased by 1%.
CAL_IA
CAL_IB
CAL_IC
0x10
0x13
0x16
Adjusts the gain of the current channels. +16384 is the typical value. The
gain is directly proportional to the CAL parameter. Allowed range is 0 to
32767. If the gain is 1% slow, CAL should be increased by 1%.
LCOMP2_A
LCOMP2_B
LCOMP2_C
0x12
0x15
0x18
This constant controls the phase compensation. No compensation occurs
when LCOMP2_n=16384. As LCOMP2_n is increased, more compensa-
tion is introduced.
CE codes for CT configuration do not use delay adjustment. These codes
use phase adjustment (PHADJ_n).
1.9.2 CALIBRATION MACRO FILE
The macro file in Figure 1-4 contains a sequence of the serial interface commands. It is a simple text file and
can be created with Notepad or an equivalent ASCII editor program. The file is executed with HyperTerminal’s
Transfer->Send Text File command.
Figure 1-4: Typical Calibration Macro File
It is possible to send the calibration macro file to the 71M6543F for “temporary” calibration. This will temporarily
change the CE data values. Upon power up, these values are refreshed back to the default values stored in
flash memory. Thus, until the flash memory is updated, the macro file must be loaded each time the part is
powered up. The macro file is run by sending it with the transfer
send text file procedure of HyperTerminal.
Use the Transfer
Send Text File command!
1.9.3 UPDATING THE DEMO CODE (HEX FILE)
The d_merge program updates the hex file (for example 6543eq5_6103_5p3c_01nov10.hex, or similar) with the
values contained in the macro file. This program is executed from a DOS command line window. Executing the
d_merge program with no arguments will display the syntax description. To merge macro.txt and
old_6543_demo.hex into new_6543_demo.hex, use the command:
d_merge old_6543_demo.hex macro.txt new_6543_demo.hex
The new hex file can be written to the 71M6543F/71M6543H through the ICE port using the ADM51 in-circuit
emulator or the TFP-2 flash programmer.
1.9.4 UPDATING CALIBRATION DATA IN FLASH OR EEPROM
It is possible to make data permanent that had been entered temporarily into the CE RAM. The transfer to
EEPROM memory is done using the following serial interface command:
>]CLS
Thus, after transferring calibration data with manual serial interface commands or with a macro file, all that has
to be done is invoking the U command.
CE0 /disable CE
]10=+16022 /CAL_IA (gain=CAL_IA/16384)
]11=+16381 /CAL_VA (gain=CAL_VA/16384)
]12=+17229 /LCOMP2_A (default 16384)
CE1 /enable CE
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Similarly, calibration data can be restored to default values using the CLD command.
After reset, calibration data is copied from the EEPROM, if present. Otherwise, calibration
data is copied from the flash memory. Writing 0xFF into the first few bytes of the EEPROM
deactivates any calibration data previously stored to the EEPROM.
1.9.5 LOADING THE CODE FOR THE 71M6543F INTO THE DEMO BOARD
Hardware Interface for Programming: The 71M6543F IC provides an interface for loading code into the inter-
nal flash memory. This interface consists of the following signals:
E_RXTX (data), E_TCLK (clock), E_RST (reset), ICE_E (ICE enable)
These signals, along with V3P3D and GND are available on the emulator headers J14.
Programming of the flash memory requires a specific in-circuit emulator, the ADM51 by Signum Systems or the
Flash Programmer (TFP-2) provided by Maxim.
Chips may also be programmed before they are soldered to the board. Gang programmers suitable for high-
volume production are available from BPM Microsystems.
In-Circuit Emulator: If firmware exists in the 71M6543F flash memory; it has to be erased before loading a new
file into memory. Figure 1-5 and Figure 1-6 show the emulator software active. In order to erase the flash
memory, the RESET button of the emulator software has to be clicked followed by the ERASE button.
To successfully erase the flash memory, the following steps have to be taken:
1) Disable the CE by writing 0x00 to address 0x2000
2) Write 0x20 to address 0x2702 (FLSH_UNLOCK[ ] register in I/O RAM)
3) Reset the demo board (RESET button or power cycle)
4) Activate the ERASE button in the WEMU51 user interface
5) Now, new code can be loaded into the flash memory
Once the flash memory is erased, the new file can be loaded using the commands File followed by Load. The
dialog box shown in Figure 1-6 will then appear making it possible to select the file to be loaded by clicking the
Browse button. Once the file is selected, pressing the OK button will load the file into the flash memory of the
71M6543F IC. At this point, the emulator probe (cable) can be removed. Once the 71M6543F IC is reset using
the reset button on the Demo Board, the new code starts executing.
Figure 1-5: Emulator Window Showing Reset and Erase Buttons (see Arrows)
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Figure 1-6: Emulator Window Showing Erased Flash Memory and File Load Menu
Flash Programmer Module (TFP-2): The operational firmware of the TFP2 will have to be upgraded to revision
1.53. Follow the instructions given in the User Manual for the TFP-2.
1.9.6 THE PROGRAMMING INTERFACE OF THE 71M6543F
Flash Downloader/ICE Interface Signals
The signals listed in Table 1-5 are necessary for communication between the TFP2 Flash Downloader or ICE
and the 71M6543F.
Signal Direction Function
ICE_E Input to the 71M6543F ICE interface is enabled when ICE_E is
pulled high
E_TCLK Output from 71M6543F Data clock
E_RXTX Bi-directional Data input/output
E_RST Bi-directional Flash Downloader Reset (active low)
Table 1-5: Flash Programming Interface Signals
The E_RST signal should only be driven by the Flash Downloader when enabling these interface
signals. The Flash Downloader must release E_RST at all other times.
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1.10 DEMO CODE
1.10.1 DEMO CODE DESCRIPTION
The Demo Board is shipped preloaded with Demo Code in the 71M6543F chip. The code revision can easily be
verified by entering the command >i via the serial interface (see section 1.8.1). Check with your local Maxim re-
presentative/FAE or for the latest revision, or obtain the latest revision from the Maxim web site.
The Demo Code offers the following features:
• It provides basic metering functions such as pulse generation, display of accumulated energy, fre-
quency, date/time, and enables the user to evaluate the parameters of the metering IC such as accu-
racy, harmonic performance, etc.
• It maintains and provides access to basic household functions such as the real-time clock (RTC).
• It provides access to control and display functions via the serial interface, enabling the user to view
and modify a variety of meter parameters such as Kh, calibration coefficients, temperature compensa-
tion etc.
• It provides libraries for access of low-level IC functions to serve as building blocks for code de-
velopment.
A detailed description of the Demo Code can be found in the Software User’s Guide (SUG). In addition, the
comments contained in the library provided with the Demo Kit can serve as useful documentation.
The Software User’s Guide contains the following information:
• Design guide
• Design reference for routines
• Tool Installation Guide
• List of library functions
• 80515 MPU Reference (hardware, instruction set, memory, registers)
1.10.2 DEMO CODE VERSIONS
Each sensor configuration has its own Demo Codes version. Using the wrong type of Demo Code will result in
malfunction. Table 1-6 shows the available Demo Code versions and their application.
Table 1-6: Demo Code Versions
File Name
Supported Configuration
Supported Demo Board
6543equ5_6103_5p3d_14feb11.hex
3 x 71M6103 with shunts 71M6543 DB REV4-0
6543equ5_6113_5p3d_14feb11.hex
3 x 71M6113 with shunts 71M6543 DB REV4-0
6543equ5_6203_5p3d_14feb11.hex
3 x 71M6203 with shunts 71M6543 DB REV4-0
6543equ5_6603_5p3d_14feb11.hex
3 x 71M6603 with shunts 71M6543 DB REV4-0
6543equ5_ct_5p3d_14feb11.hex
CT 71M6543 DB REV5-0
1.10.3 IMPORTANT MPU ADDRESSES
In the Demo Code, certain MPU XRAM parameters have been given addresses in order to permit easy external
access. These variables can be read via the command line interface (if available), with the )n$ command and
written with the )n=xx command where n is the word address. Note that accumulation variables are 64 bits long
and are accessed with )n$$ (read) and )n=hh=ll (write) in the case of accumulation variables.
The first part of the table, the addresses )00..)1F, contains adjustments, i.e. numbers that may need adjustment
in a demonstration meter, and so are part of the calibration for demo code. In a reference meter, these may be
in an unchanging table in code space.
The second part, )20..)2F, pertains to calibration, i.e. variables that are likely to need individual adjustments for
quality production meters.
The third part, )30…, pertains to measurements, i.e. variables and registers that may need to be read in a
demonstration meter.
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Table 1-7: MPU XRAM Locations
Name Purpose LSB Default )? Signed? Bits
i_min
Metering element
enters creep mode
if current is below
this value.
If 0, creep logic is
disabled. In creep
mode, on each me-
tering element, Wh,
VARh, i0sqsum,
and other items are
zeroed.
Same units as CE’s i0sqsum. 0.08A )0 signed 32
cfg Configure meter
operation on the fly.
bit0: 1=Display KWh.
bit1: 1=clear accumulators, er-
rors, etc. (e.g. “)1=2”)
bit2: 1=Reset demand. (e.g.
“)1=4”)
bit3: 1=CE Raw mode. MPU
does not change CE values with
creep or small current calcula-
tions.
bit5: 1= Send a message once
per second for IEC 62056-217
Mode D on UART 1, at 2400
BAUD, even parity. The meter’s
serial number and current Wh
display are sent as data. UART
1 is routed to an IR LED if pos-
sible. Mode D data fields are
prefaced with OBIS codes in
legacy format. 7,1
bit6: 1=Auto calibration mode 1
bit7: 1=Enable Tamper Detect
2,1
0
Do nothing spe-
cial.
)1 N/A 8
v_min
error if below. Also
creep.*
Below this, low volt-
age seconds are
counted. Voltage,
Wh, VARh, Fre-
quency, and other
voltage-dependent
items are zeroed.
Same units as CE’s v0sqsum. 40V )2 signed 32
i_max
Scaling Maximum
Amps for standard
sensor.
0.1A
110.5 for 200
μOhm shunt
with 8x preamp.
884.0 A for 200
μOhm shunt,
442.0A for 400
μOhm shunt.
)3 signed 16
v_max Scaling Maximum
Volts for PCB 0.1V 600 V, for the
Demo Board. )4 signed 16
i_limit Error if exceeded. Same units as CE’s i0sqsum.
50.9A =
30A*sqrt(2)
*120%
)5 signed 32
v_limit Error if exceeded.* Same units as CE’s v0sqsum.
407.3V =
240V*sqrt(2)
*120%
)6 signed 32
71M6543 Demo Board User’s Manual
Page: 26 of 91 v5
wrate_mpu Convert from CE
counts to pulses.
CE’s w0sum units per pulse,
rounded up to next largest CE
count so Wh accumulation and
display is always rounded down.
3.2 Wh )7 signed 32
interval
The number of
minutes of a de-
mand interval.
Count of minutes.
(60/interval)*interval = 60. 2 minutes )8 unsigned 8
mains_hz
Expected number of
cycles per second
of mains. 0 disables
the software RTC
run from mains.
Hz 0 )9 unsigned 8
temp_cal1
Machine-readable
units per 0.1C
See data sheet. Temperature is
calculated as temp = (meas-
ured_temp – temp_datum)
/temp_cal1 + temp_cal0
See data sheet. )A signed 32
mtr_cal1
[0..3]9
Linear temperature
calibration for meter
elements A..D.
ppm*(T - mtr_datum), in 0.1˚C 150 )B..E signed 16
mtr_cal2
[0..3]9
Squared tempera-
ture calibration for
meter elements
A..D.
ppm2*(T - mtr_datum)2, in 0.1˚C -392 )F..1
2 signed 16
y_datum Center temperature
of the crystal. 0.1 C 25C )13 signed 16
y_cal1 5 RTC adjust, linear
by temp. 10 ppb*(T - y_datum), in 0.1˚C 0 )14 signed 16
y_cal2 5 RTC adjust,
squared by temp. 1 ppb*(T - y_datum)2, in 0.1˚C 38 )15 signed 16
s_cal 1
Accumulation inter-
vals of
Autocalibration
Count of accumulation intervals
of calibration.
accumulation
intervals cover
both chop polar-
ities.
)C signed 16
v_cal 1 Volts of
Autocalibration
0.1 V rms of AC signal applied
to all elements during calibra-
tion.
2400
240 V is the
default full-scale
for meter test.
)D signed 16
i_cal 1 Amps of
Autocalibration
0.1 A rms of AC signal applied
to all elements during calibra-
tion. Power factor of calibration
signal must be 1.
300
30 A is the de-
fault full-scale
for meter test.
)E signed 16
71M6543 Demo Board User’s Manual
Page: 27 of 91 v5
lcd_idx Selects LCD’s cur-
rent display.
0: Meter identification. (“#”)
1: Display variation from calibra-
tion temperature, 0.1C
2: Display mains Hz, 0.1 Hz
3: mWh, total
4: mWh total exported.
5: mVARh, total.
6: mVARh, total exported.
7:mVAh, total
8: Operating hours.
9: Time of day
10: Calendar date
11: Power factor, total
12: Angle between phase 0 & 1
13: Main edge count, last accu-
mulation.
14: KW, instantaneous total
15: V, instantaneous max of all
phases.
16: A, total
17: V, Battery (“VB”)
18: Seconds, bad power (“BPS”)
19: Seconds, tamper (- = tamper
in progress) (“TS”)
20: LCD Test
Scrolling not standard for these:
111: PF, phase 0
112: Angle, phase 0 & 1
114: KW, phase 0
115: V, phase 0
116: A, phase 0
211: PF, phase 1
212: Angle, phase 0 & 2
214: KW, phase 1
215: V, phase 1
216: A, phase 1
311: PF, phase 2
312: Angle, phase 2.0
314: KW, phase 2
315: V, phase 2
316: A, phase 2
416: A, neutral (measured)
3 )19 signed 16
lcd_bit Defines sequence
of LCD displays.
The value is a bit mask that de-
scribes a scrolling display se-
quence. Each set bit permits a
display with an lcd_idx value
from 0..31. Each is displayed
for 7 seconds. Ordered by in-
creasing bit number. If value is
zero, display does not change.
0 )1A unsigned 32
mfr_id 6
Manufacturer’s ID
text string of the
meter
3 ASCII bytes, in MSB of 32-bit
number. Least significant byte
should be zero. For AMR
demonstrations, sent as the
manufacturer’s ID of the meter.
“TSC”,
0x54534300 )1B unsigned 32
71M6543 Demo Board User’s Manual
Page: 28 of 91 v5
i_max2 4
Like i_max, except
for the 2nd current
sensor.
Currents, Wh etc.
using currents from
the second sensor
are rescaled into the
same units as the
first current sensor.
0.1 Amps 208 A (2080) )1C signed 16
in_limit 3 Maximum valid neu-
tral current. Same units as CE’s i3sqsum. 0.1A )1D signed 32
in_wait 3
The time that neu-
tral current can ex-
ceed n_max before
the neutral error is
asserted.
Count of accumulation intervals. 10 secs. )1E signed 16
Reserved )1F
meter_id 8 Identification num-
ber of meter.
32 bit unsigned number. For
AMR demonstrations, this is
sent in decimal as the identifica-
tion number of the meter.
100000000 )20 signed 32
temp_datum 8
Count of tempera-
ture sensor at cali-
bration.
See data sheet. Temperature is
calculated as temp = (meas-
ured_temp –
temp_datum)/temp_cal1 +
temp_cal0
n/a )21 signed 32
mtr_datum[0.
.3]8
Center temperature
of a meter element’s
temperature curve.
0.1C 22C )22..
25 signed 16
rtca_adj 8
Default value for
RTCA_ADJ, the
crystal’s capacitor
adjustment.
See data sheet. Set from hard-
ware value when hardware is
changed.
Hardware de-
fault (see data
sheet).
)26 unsigned 8
y_cal0 5,8 RTC offset rate ad-
just 100ppb 0 )27 signed 16
v_bat_min 8 Minimum valid bat-
tery voltage.
Units of hardware’s battery
measurement register.
2V on a real
PCB; should be
adjusted for
battery and
chip.
)28 signed 32
cal_cnt
Count of calibra-
tions. In demo
code, it also checks
adjustments.
Counts number of times calibra-
tion is saved, to a maximum of
255.
0 )29 unsigned 8
ver_hash
Checked to prevent
old calibration data
from being used by
new code. Value
that changes with
the banner text, and
therefore with the
version, date and
time.
Uses data_ok() to calculate a
value from the string. n/a )2A unsigned 8
data_ok_cal
Checks calibrations.
In demo code, it
also checks adjust-
ments.
Checked by data_ok() of calibra-
tion value. n/a )2B unsigned 16
Reserved )2C.
)2F
71M6543 Demo Board User’s Manual
Page: 29 of 91 v5
state_bit_ar
y
Status of meter.
Nonvolatile.
Bits:
See table below. 0 = no errors )30 unsigned 32
wh_im Wh energy register.
Nonvolatile.
First 32-bit number is a count of
pulses, =3.2 Wh in 3-phase me-
ters, or 1 in 1-phase. A frac-
tional pulse is present in the CE
data, but not preserved.
n/a )31 64
wh_ex
Wh exported energy
register. Nonvola-
tile.
Like wh_im n/a )32 64
varh_im VARh register.
Nonvolatile. Like wh_im n/a )33 64
varh_ex VARh exported reg-
ister. Nonvolatile. Like wh_im n/a )34 64
dmd_max Maximum demand,
W Units of w0sum n/a )35 signed 32
dmd_max_rtc Time of maximum
demand.
Standard time and date struc-
ture.
year, month,
date, hour, min
)36..
3A unsigned 7x8
v_bat
Battery voltage at
last measurement.
Volatile; not saved
on power failure.
0.1V n/a )3B signed 8
acc_cnt
Count of accumula-
tion intervals since
reset, or last clear.
Cleared with )1=2 or
meter read. Volatile;
not saved on power
failure.
count n/a )3C signed 32
tamper_sec
Counts seconds
that tamper errors
were asserted.
Cleared with )1=2 or
meter read. Nonvol-
atile.
This is a tamper measurement. n/a )3D signed 32
sag_sec
Counts seconds
that voltage low
error occurred. or
meter read. Nonvol-
atile.
This is a power quality meas-
urement. n/a )3E signed 32
in_sec 3
Counts seconds
that neutral current
error was asserted.
Cleared with )1=2 or
meter read. Nonvol-
atile.
This is a power quality meas-
urement. n/a )3F signed 32
rtc_copy
Clock time and date
when data was last
read from the RTC.
Standard time and date struc-
ture. year, month, date, hour,
min, sec
n/a )40..
45 unsigned 8*7
save_cnt Number of power
register saves. n/a n/a )46 unsigned 16
data_ok_reg
Checks data. n/a n/a )47 unsigned 16
1 Valid only when autocalibration is integrated. Meters with metering equations with differential currents or voltages do
not normally support autocalibration.
2 Requires features not in some demo PCBs.
71M6543 Demo Board User’s Manual
Page: 30 of 91 v5
3 Three-phase ICs only. Some CE codes calculate neutral current rather than measuring it. Consult the CE documenta-
tion.
4 Only in systems with two current sensors.
5 High accuracy use of this feature may require a calibrated clock.
6 IEC 62056 Manufacturers’ IDs are allocated by the FLAG association. Maxim does not own or profit from the FLAG
association. Maxim’s default id may not conform, and is for demonstration purposes only.
7 Nothing in the document should be interpreted as a guarantee of conformance to a 3rd party software specification.
Conformance testing is the responsibility of a meter manufacturer.
8 May require calibration for best accuracy.
9 Calibration item in high-precision “H” series meters (71M6543H only).
Table 1-8: Bits in the MPU Status Word
Name Bit
No.
Explanation
MINIA
0
IA is below IThrshld. Current for this phase is in creep.
MINIB
1
IB is below IThrshld. Current for this phase is in creep.
MINIC
2
IC is below IThrshld. Current for this phase is in creep.
MINVA
3
VA is below VThrshld. Voltage for this phase is in creep.
MINVB
4
VB is below VThrshld. Voltage for this phase is in creep.
MINVC
5
VC is below VThrshld. Voltage for this phase is in creep.
CREEPV
6
All voltages are below VThrshld.
CREEP
7
There is no combination of current and voltage on any phase.
SOFTWARE
8
A software defect was detected. error_software() was called. E.g.: An impossible value oc-
curred in a selection, or the timers ran out.
NEUTRAL
9
Neutral current was above in_limit for more than in_wait seconds.
SPURIOUS
10
An unexpected interrupt was detected.
SAG
11
Voltage was below VThrshld for more than in_wait seconds
DEMAND
12
Demand was too big (too many watts) to be credible.
CALIBRATION
13
Set after reset if the read of the calibration data has a bad checksum, or is from an earlier ver-
sion of software. The default values should be present.
RTC_UNSET
14
Set when the clock’s current reading is A) Obtained after a cold start, indicating that there was
no battery power, and therefore the clock has to be invalid. B) More than a year after the previ-
ously saved reading, or C) Earlier than the previously saved reading. In this case, the clock’s
time is preserved, but the clock can’t be trusted.
HARDWARE
15
An impossible hardware condition was detected. For example, the woftware times out waiting
for RTC_RD to become zero.
BATTERY_BAD
16
Just after midnight, the demo code sets this bit if VBat < VBatMin. The read is infrequent to
reduce battery loading to very low values. When the battery voltage is being displayed, the
read occurs every second, for up to 20 seconds.
REGISTER_BAD
17
Set after reset when the read of the power register data has a bad longitudinal redundancy
check or bad software version in all 5 copies. Unlikely to be an accident.
RTC_TAMPER
18
Clock set to a new value more than two hours from the previous value.
TAMPER
19
Tamper was detected. Normally this is a power tamper detected in the creep logic. For exam-
ple, current detected with no voltage.
Table 1-9 contains LSB values for the CE registers. All values are based on the following settings:
• Gain in amplifier for IAP/IAN pins selected to 1.
• 71M6103, 71M6113, or 71M6203 Remote Sensor Interface is used.
Note that some of the register contents can be zeroed out by the MPU when it applies functions contained in its
creep logic.
71M6543 Demo Board User’s Manual
Page: 31 of 91 v5
1.10.4 LSB VALUES IN CE REGISTERS
Table 1-9: CE Registers and Associated LSB Values
Register Name LSB Value Comment
W0SUM_X
W1SUM_X
W2SUM_X
1.55124*10-12*IMAX*VMAX The real energy for elements A, B, and C, measured in Wh per accu-
mulation interval
VAR0SUM_X
VAR1SUM_X
VAR2SUM_X
1.55124*10-12*IMAX*VMAX The reactive energy for elements A, B, and C, measured in VARh per
accumulation interval
I0SQSUM_X
I1SQSUM_X
I2SQSUM_X
INSQSUM_X
2.55872*10-12*IMAX*VMAX The sum of squared current samples in elements A, B, C, and neutral.
This value is the basis for the IRMS calculation performed in the MPU.
V0SQSUM_X
V1SQSUM_X
V1SQSUM_X
9.40448*10-13*IMAX*VMAX The sum of squared voltage samples in elements A, B, and C.
1.10.5 CALCULATING IMAX AND KH
The relationship between the resistance of the shunt resistors and the system variable IMAX is determined by
the type of Remote Sensor Interface used, and is as follows:
IMAX = 0.044194 / RS for the 71M6603
IMAX = 0.019642 / RS for the 71M61X1
IMAX = 0.012627 / RS for the 71M6203
Where:
RS = Shunt resistance in Ω
Table 1-10 shows IMAX values resulting from possible combinations of the shunt resistance value and the type
of 71M6x0x Remote Sensor Interface used for the application.
Table 1-10: IMAX for Various Shunt Resistance Values and Remote Sensor Types
Remote Sen-
sor Interface
Rated
Current
[A]
Max. RMS
Voltage at
IAP/IAN [mV]
Shunt Re-
sistor Value
[µΩ]
IMAX
[A]
IMAX En-
try at MPU
0x03
WRATE for kH =
3.2, VMAX = 600
V, X = 0.09375
71M6603 60 44.2
500
88.39
+884
3829
400
110.49
+1105
4786
300
147.31
+1473
6381
250
176.78
+1768
7657
200
220.97
+2209
9572
160
276.21
+2762
11965
120
368.28
+3683
15953
71M6103,
71M6113 100 19.64
250
78.57
786
3403
200
98.21
982
4254
160
122.76
1228
5318
120
163.68
1637
7090
100
196.42
1964
8508
71M6203,
71M6203 200 12.63
75
168.36
1684
7293
50
252.54
2525
10939
25
505.08
5050
21878
71M6543 Demo Board User’s Manual
Page: 32 of 91 v5
The meter constant kh (Wh per pulse) is calculated as follows:
Kh = 54.5793*VMAX*IMAX / (SUM_SAMPS*WRATE*X),
where
VMAX = RMS voltage at the meter input corresponding to 176.8 mV RMS at the VA pin of the
71M6543. This value is determines by the divider ratio of the voltage divider resistors. For the
71M6543 Demo Board, this value is 600.
IMAX/ = RMS current through one current sensor corresponding to the maximum RMS voltage at the
input pins of the 71M6103, as determined by the formula above.
SUM_SAMPS = The value in the SUM_SAMPS register in I/O RAM (2520 for this version of the Demo
Code).
WRATE = The value in the pulse rate adjustment register of the CE.
X = The pulse rate adjustment modifier, determined by the PULSE_FAST and PULSE_SLOW bits in
the CECONFIG register.
For the 71M6103, a kh of 3.2 (3.2 Wh per pulse) is achieved by the following combination of system settings:
VMAX = 600 V
IMAX/ = 163.7 A, based on RS = 120 μΩ
SUM_SAMPS = 2520
WRATE = 7090
X = 0.09375, based on PULSE_FAST =0 and PULSE_SLOW = 1
The calculations shown above are simplified if the calibration spreadsheet provided with each Demo Kit is used.
Figure 1-7 shows an example: The user enters data in the yellow fields, and the results will show in the green
fields.
Figure 1-7: Worksheet from Calibration Spreadsheets REV 6.0
1.10.6 DETERMINING THE TYPE OF 71M6X0X
Sometimes it is useful to be able to determine the type of 71M6x0x Remote Sensor Interface that is mounted on
the Demo Board. The CLI can be used to find out which Remote Sensor Interface is present, using the following
steps:
1) Type 6R1.14, 6R2.14, or 6R3.14, depending on which phase is tested.
2) The CLI will respond with a two-byte hex value, e.g. E9DB.
3) Write the hex value out as binary sequence, e.g. 1110 1001 1101 1011. Bits 4 and 5 determine the
type of the 71M6x0x Remote Sensor Interface, as shown in Table 1-11.
71M6543 Demo Board User’s Manual
Page: 33 of 91 v5
Table 1-11: Identification of 71M6x0x Remote Sensor Types
Bit 5/Bit 4 71M6x0x Remote Interface Current
[A]
For Accuracy Class (%)
00 71M6601 or 71M6603 60 1
01 71M6103 (Polyphase) or 100 1
71M6113 (Polyphase) 0.5
10 71M6201 or 71M6203 200 0.2
11 Invalid -- --
1.10.7 COMMUNICATING WITH THE 71M6X0X
Some commands are useful to communicate with the 71M6x0x Remote Sensor Interface for the purpose of test
and diagnosis. Some useful commands are:
1) 6C1.42 – this command causes the 71M6x0x Remote Sensor Interface to output its reference voltage
on the TMUX pin (pin 5).
2) 6R1.20 – this command returns the reading from the temperature sensor (STEMP) of the 71M6x0x
Remote Sensor Interface in a two-byte hexadecimal format (e.g. FFDF). Negative readings are sig-
naled by the MSB being 1.
T = 22°C + (STEMP*0.33 - (STEMP2)*0.00003)°C
Example: For STEMP = 0xFFDF the decimal equivalent is -32. The temperature calculates to 22°C –
10.59°C = 11.4°C.
Note that the IC temperature is averaged and displayed more accurately with the M1 command.
1.10.8 BOOTLOADER FEATURE
Demo Codes 5.4F and later are equipped with a bootloader feature. This feature allows the loading of code via
the serial interface (USB connector CN1) when a Signum ADM51 emulator or Maxim TFP2 Flash Loader is not
available.
The bootloader functions as follows:
1) Meter code must be modified in order to be loaded by the bootloader. The meter code must start at ad-
dress 0x0400, and its interrupt vector table must also start at 0x400. The bootloader itself is located at ad-
dress 0x0000 and must be loaded into the IC by some method if the flash memory of the 71M6543 is empty
or if code of a previous revision is loaded. The bootloader is part of Demo Code 5.4F.
2) The bootloader loads Intel hex-86 files at 38,400 baud 8 bits, no parity. It will only accept record types 0, 4
and 1, which are the types produced by Maxim’s Teridian bank_merge program or checksum program, and
the Keil compiler (PK51). No records may overlap. (Keil, bank_merge and checksum produce this style of
hex file by default.)
The records from 0x00000 to 0x00400 are ignored, so that the bootloader can't overwrite itself.
3) If the bootloader load process is not invoked, the bootloader jumps to address 0x0400 and executes the
code found there.
4) A detailed description of the bootloader can be found in the _readme.txt file contained in the source code
ZIP package (folder 6543_5p4f_14dec11\Config\Series6540\BtLd).
For a 71M6543 Demo Board containing code with the bootloader, instructions for loading new code are as fol-
lows:
1) Connect a PC running HyperTerminal or a similar terminal program to the 71M6543 Demo Board. Set the
program to 38,400 baud 8 bits, no parity, XON/XOFF flow control.
2) Turn off the power to the 71M6543 Demo Board.
3) Install a jumper from board ground to the VARh pulse output (JP7, right pin), which is also SEGDIO2. A low
voltage on this pin signals to the bootloader that new code should be loaded via the UART.
4) Apply power to the meter.
5) After a brief delay, the Wh pulse LED (D5) will light up (SEGDIO1). The bootloader should send a ":" on the
UART to the PC. If this occurs, the flash is erased, and the 71M6543 Demo Board is ready to load code.
- If this does not occur, check the jumper, and reset or repower the unit
- If the Wh LED still does not light up, then the boot code is not installed.
71M6543 Demo Board User’s Manual
Page: 34 of 91 v5
- If the Wh LED lights up, but the ":" does not appear, debug the RS-232 wiring. Possible issues are that the
baud rate is not 38400 baud, or that the wiring is wrong, (debug using a known-good meter), or that the
terminal program in the PC is not working.
6) Send the Intel hex file built for operation with the bootloader (e.g. 6543eq5_6103_5p4f_14dec11.hex) using
the ‘Send Text File’ command of HyperTerminal.
7) During the load procedure, the Wh LED will blink. Once the load process is completed it stops blinking.
The Wh LED should remain on solidly at the completion of the load procedure, which indicates an error-free
load. If the LED turns off at the end, an error must have occurred. In this case the load should be repeated.
The bootloader sends a "1" on the UART if the load succeeded, and "0" if it failed.
8) Check the display of terminal program (e.g. the PC running Hyperterminal). If no checksum error has oc-
curred, the bootloader sends a 1 on the UART. In case of an error, reset the 71M6543 Demo Board, or turn
it off and on, and reload the code.
9) Remove the jumper on JP7. This will cause the loaded Demo Code to start.
71M6543 Demo Board User’s Manual
Page: 35 of 91 v5
2 APPLICATION INFORMATION
2.1 CALIBRATION THEORY
A typical meter has phase and gain errors as shown by φS, AXI, and AXV in Figure 2-1. Following the typical me-
ter convention of current phase being in the lag direction, the small amount of phase lead in a typical current
sensor is represented as -φS. The errors shown in Figure 2-1 represent the sum of all gain and phase errors.
They include errors in voltage attenuators, current sensors, and in ADC gains. In other words, no errors are
made in the ‘input’ or ‘meter’ boxes.
Π
I
V
φ
L
INPUT
−φ
S
A
XI
A
XV
ERRORS
)
cos(
L
IV
IDEAL
φ
=
)
cos(
S
L
XV
XI
A
A
IV
ACTUAL
φ
φ
−
=
1
−
=
−
≡
IDEAL
ACTUAL
IDEAL
IDEAL
ACTUAL
ERROR
W
I
RMS
METER
V
RMS
XI
A
I
ACTUAL
I
IDEAL
=
=
,
XV
A
V
ACTUAL
V
IDEAL
=
=
,
φ
L
is phase lag
φ
S
is phase lead
Figure 2-1: Watt Meter with Gain and Phase Errors.
During the calibration phase, we measure errors and then introduce correction factors to nullify their effect. With
three unknowns to determine, we must make at least three measurements. If we make more measurements, we
can average the results.
2.1.1 CALIBRATION WITH THREE MEASUREMENTS
The simplest calibration method is to make three measurements. Typically, a voltage measurement and two
Watt-hour (Wh) measurements are made. A voltage display can be obtained for test purposes via the command
>MR2.1 in the serial interface.
Let’s say the voltage measurement has the error EV and the two Wh measurements have errors E0 and E60,
where E0 is measured with φL = 0 and E60 is measured with φL = 60. These values should be simple ratios—not
percentage values. They should be zero when the meter is accurate and negative when the meter runs slow.
The fundamental frequency is f0. T is equal to 1/fS, where fS is the sample frequency (2560.62Hz). Set all cali-
bration factors to nominal: CAL_IA = 16384, CAL_VA = 16384, LCOMP2_A = 16384.
Note: The derivation of the calibration formulae is provided for CTs, where a phase adjustment is performed to
compensate for the phase error of the CT. For operation with 71M6xxx Remote Sensor Interfaces, a delay
compensation LCOMP2_n is used. Spreadsheets are available to calculate the calibration coefficients for all
hardware configurations.
2
71M6543 Demo Board User’s Manual
Page: 36 of 91 v5
From the voltage measurement, we determine that
1.
1+=
VXV
EA
We use the other two measurements to determine φS and AXI.
2.
1)cos(1
)0cos(
)0cos(
0
−=−
−
=
SXIXV
SXIXV
AA
IV
AAIV
E
φ
φ
2a.
)cos(
1
0
S
XIXV
E
AA
φ
+
=
3.
1
)60cos(
)60cos(
1
)60cos(
)60cos(
60
−
−
=−
−
=
S
XIXV
SXIXV
AA
IV
AAIV
E
φφ
3a.
[ ]
1
)60cos(
)
sin()60sin()cos()60cos(
60
−
+
=
SSXIXV
AA
E
φφ
1)sin()60tan()cos( −+=
SXIXVSXIXV
AAAA
φφ
Combining 2a and 3a:
4.
)tan()60tan()1( 0060 S
EEE
φ
++=
5.
)60tan()1(
)tan(
0
060
+
−
=E
EE
S
φ
6.
+
−
=−
)60tan()1(
tan
0
060
1
E
EE
S
φ
and from 2a:
7.
)cos(
1
0
SXV
XI A
E
A
φ
+
=
Now that we know the AXV, AXI, and φS errors, we calculate the new calibration voltage gain coefficient from the
previous ones:
XV
NEW
A
VCAL
VCAL _
_=
We calculate PHADJ from φS, the desired phase lag:
[ ]
[ ]
−−−−
−−−+
=
−−
−−
)2cos()21(1)tan()2sin()21(
)2cos()21(2)21(1)tan(
2
0
9
0
9
0
929
20
TfTf
Tf
PHADJ
S
S
πφπ
πφ
And we calculate the new calibration current gain coefficient, including compensation for a slight gain increase
in the phase calibration circuit.
29
0
9
0
92020
)21()2cos()21(21
))2cos()21(222(2
1
1_
_
−−
−−−
−+−−
−−+
+
=
Tf
TfPHADJPHADJ
A
ICAL
ICAL
XI
NEW
π
π
71M6543 Demo Board User’s Manual
Page: 37 of 91 v5
2.1.2 CALIBRATION WITH FIVE MEASUREMENTS
The five measurement method provides more orthogonality between the gain and phase error derivations. This
method involves measuring EV, E0, E180, E60, and E300. Again, set all calibration factors to nominal, i.e. CAL_IA
= 16384, CAL_VA = 16384, PHADJ_A = 0.
Note: The derivation of the calibration formulae is provided for CTs, where a phase adjustment is performed to
compensate for the phase error of the CT. For operation with 71M6xxx Remote Sensor Interfaces, a delay
compensation LCOMP2_n is used. Spreadsheets are available to calculate the calibration coefficients for all
hardware configurations.
First, calculate AXV from EV:
1.
1+= VXV EA
Calculate AXI from E0 and E180:
2.
1)cos(1
)0cos(
)0cos(
0
−=−
−
=
SXIXV
SXIXV
AA
IV
AAIV
E
φ
φ
3.
1)cos(1
)180cos(
)180cos(
180
−=−
−
=
SXIXV
SXIXV
AA
IV
AAIV
E
φ
φ
4.
2)cos(2
1800
−=+
SXIXV
AAEE
φ
5.
)cos(2
2
1800
S
XIXV
EE
AA
φ
++
=
6.
)cos(
12)(
1800
SXV
XI
A
EE
A
φ
++
=
Use above results along with E60 and E300 to calculate φS.
7.
1
)60cos(
)60cos(
60
−
−
=IV
AAIV
E
SXI
XV
φ
1)sin()60tan()cos( −+=
SXIXVSXIXV
AAAA
φφ
8.
1
)60cos(
)60cos(
300
−
−
−−
=IV
AAIV
E
SXIXV
φ
1)sin()60tan()cos( −−= SXIXVSXIXV AAAA
φφ
Subtract 8 from 7
9.
)sin()60tan(2
30060 SXIXV
AAEE
φ
=−
use equation 5:
10.
)sin()60tan(
)cos(
2
1800
30060 S
S
EE
EE
φ
φ
++
=−
11.
)tan(
)60tan()2(
180030060 S
EEEE
φ
++=−
12.
++
−
=−
)2)(60tan(
)(
tan
1800
30060
1
EE
EE
S
φ
71M6543 Demo Board User’s Manual
Page: 38 of 91 v5
Now that we know the AXV, AXI, and φS errors, we calculate the new calibration voltage gain coefficient from the
previous ones:
XV
NEW
A
VCAL
VCAL _
_=
We calculate PHADJ from φS, the desired phase lag:
[ ]
[ ]
−−−−
−−−+
=
−−
−−
)2cos()21(1)tan()2sin()21(
)2cos()21(2)21(1)tan(
2
0
9
0
9
0
929
20
TfTf
Tf
PHADJ
S
S
πφπ
πφ
And we calculate the new calibration current gain coefficient, including compensation for a slight gain increase
in the phase calibration circuit.
29
0
9
0
92020
)21()2cos()21(21
))2cos()21(222(2
1
1_
_
−−
−−−
−+−−
−−+
+
=
Tf
TfPHADJPHADJ
A
ICAL
ICAL
XI
NEW
π
π
2.2 CALIBRATION PROCEDURES
2.2.1 CALIBRATION EQUIPMENT
Calibration requires that a calibration system is used, i.e. equipment that applies accurate voltage, load current
and load angle to the unit being calibrated, while measuring the response from the unit being calibrated in a re-
peatable way. By repeatable we mean that the calibration system is synchronized to the meter being calibrated.
Best results are achieved when the first pulse from the meter opens the measurement window of the calibration
system. This mode of operation is opposed to a calibrator that opens the measurement window at random time
and that therefore may or may not catch certain pulses emitted by the meter.
It is essential for a valid meter calibration to have the voltage stabilized a few seconds be-
fore the current is applied. This enables the Demo Code to initialize the 71M6543F and to
stabilize the PLLs and filters in the CE. This method of operation is consistent with meter
applications in the field as well as with metering standards.
During calibration of any phase, a stable mains voltage has to be present on phase A. This
enables the CE processing mechanism of the 71M6543F necessary to obtain a stable cali-
bration.
2.2.2 DETAILED CALIBRATION PROCEDURES
The procedures below show how to calibrate a meter phase with either three or five measurements. The
PHADJ equations apply only when a current transformer is used for the phase in question. Note that positive
load angles correspond to lagging current (see Figure 2-2).
71M6543 Demo Board User’s Manual
Page: 39 of 91 v5
Figure 2-2: Phase Angle Definitions
The calibration procedures described below should be followed after interfacing the voltage and current sensors
to the 71M6543F chip. When properly interfaced, the V3P3 power supply is connected to the meter neutral and
is the DC reference for each input. Each voltage and current waveform, as seen by the 71M6543F, is scaled to
be less than 250mV (peak).
2.2.3 CALIBRATION PROCEDURE WITH THREE MEASUREMENTS
Each phase is calibrated individually. The calibration procedure is as follows:
1) The calibration factors for all phases are reset to their default values, i.e. CAL_In = CAL_Vn = 16384,
and LCOMP2_n = 16384.
2) An RMS voltage Videal consistent with the meter’s nominal voltage is applied, and the RMS reading
Vactual of the meter is recorded. The voltage reading error Axv is determined as
Axv = (Vactual - Videal ) / Videal
3) Apply the nominal load current at phase angles 0° and 60°, measure the Wh energy and record the er-
rors E0 AND E60.
4) Calculate the new calibration factors CAL_In, CAL_Vn, and LCOMP2_n, using the formulae present-
ed in section 2.1.1 or using the spreadsheet presented in section 2.2.5.
5) Apply the new calibration factors CAL_In, CAL_Vn, and LCOMP2_n to the meter. The memory loca-
tions for these factors are given in section 1.9.1.
6) Test the meter at nominal current and, if desired, at lower and higher currents and various phase an-
gles to confirm the desired accuracy.
7) Store the new calibration factors CAL_In, CAL_Vn, and LCOMP2_n in the EEPROM or FLASH
memory of the meter. If the calibration is performed on a Teridian Demo Board, the methods involving
the command line interface, as shown in sections 1.9.3 and 1.9.4, can be used.
8) Repeat the steps 1 through 7 for each phase.
Tip: Step 2 and the energy measurement at 0° of step 3 can be combined into one step.
Voltage
Current
+60°
Using EnergyGenerating Energy
Current lags
voltage
(inductive
)
Current leads
voltage
(capacitive
)
-60°
Voltage
Positive
direction
71M6543 Demo Board User’s Manual
Page: 40 of 91 v5
2.2.4 CALIBRATION PROCEDURE WITH FIVE MEASUREMENTS
Each phase is calibrated individually. The calibration procedure is as follows:
1) The calibration factors for all phases are reset to their default values, i.e. CAL_In = CAL_Vn = 16384,
and LCOMP2_n = 0.
2) An RMS voltage Videal consistent with the meter’s nominal voltage is applied, and the RMS reading
Vactual of the meter is recorded. The voltage reading error Axv is determined as
Axv = (Vactual - Videal ) / Videal
3) Apply the nominal load current at phase angles 0°, 60°, 180° and –60° (-300°). Measure the Wh ener-
gy each time and record the errors E0, E60, E180, and E300.
4) Calculate the new calibration factors CAL_In, CAL_Vn, and LCOMP2_n, using the formulae present-
ed in section 2.1.2 or using the spreadsheet presented in section 2.2.5.
5) Apply the new calibration factors CAL_In, CAL_Vn, and LCOMP2_n to the meter. The memory loca-
tions for these factors are given in section 1.9.1.
6) Test the meter at nominal current and, if desired, at lower and higher currents and various phase an-
gles to confirm the desired accuracy.
7) Store the new calibration factors CAL_In, CAL_Vn, and LCOMP2_n in the EEPROM or FLASH
memory of the meter. If a Demo Board is calibrated, the methods involving the command line interface
shown in sections 1.9.3 and 1.9.4 can be used.
8) Repeat the steps 1 through 7 for each phase.
Tip: Step 2 and the energy measurement at 0° of step 3 can be combined into one step.
2.2.5 CALIBRATION SPREADSHEETS
Calibration spreadsheets are available on the Maxim web site (www.maxim-ic.com). Figure 2-3 shows the
spreadsheet for three measurements. Figure 2-4 shows the spreadsheet for five measurements with three
phases.
Use the standard calibration spreadsheets (for 71M651x, 71M652x, or 71M653x) when calibrating meters with
CTs. These spreadsheets will provide results for the PHADJ_n parameters instead of the LCOMP2_n parame-
ters.
For the calibration, data should be entered into the calibration spreadsheets as follows:
1. Calibration is performed one phase at a time.
2. Results from measurements are generally entered in the yellow fields. Intermediate results and calibra-
tion factors will show in the green fields.
3. The line frequency used (50 or 60Hz) is entered in the yellow field labeled AC frequency.
4. After the voltage measurement, measured (observed) and expected (actually applied) voltages are en-
tered in the yellow fields labeled “Expected Voltage” and “Measured Voltage”. The error for the voltage
measurement will then show in the green field above the two voltage entries.
5. The relative error from the energy measurements at 0° and 60° are entered in the yellow fields labeled
“Energy reading at 0°” and “Energy reading at 60°”. The corresponding error, expressed as a fraction
will then show in the two green fields to the right of the energy reading fields.
6. The spreadsheet will calculate the calibration factors CAL_IA, CAL_VA, and LCOMP2_A from the in-
formation entered so far and display them in the green fields in the column underneath the label “new”.
7. If the calibration was performed on a meter with non-default calibration factors, these factors can be
entered in the yellow fields in the column underneath the label “old”. For a meter with default calibra-
tion factors, the entries in the column underneath “old” should be at the default value (16384).
71M6543 Demo Board User’s Manual
Page: 41 of 91 v5
Figure 2-3: Calibration Spreadsheet for Three Measurements
Note: The values for LCOMP2_n may have to be changed slightly depending on shunt sensor and cable in-
ductance. The values from the spreadsheets provide starting points. For example, if after calibration the error
or 0° load angle is 0.024%, but +1.25% at 60° and -1.18% at 300°, LCOMP2_n should be increased to mini-
mize the errors at 60° and at 300°.
71M6543 Demo Board User’s Manual
Page: 42 of 91 v5
Figure 2-4: Calibration Spreadsheet for Five Measurements
Note: The spreadsheets shown above apply to calibration for systems with 71M6xxx Remote Sensor Interfaces.
For CT-bases meters, the regular spreadsheets (also used for the 71M6513, 71M6533, and 71M6534) should
be used.
2.2.6 COMPENSATING FOR NON-LINEARITIES
Nonlinearity is most noticeable at low currents, as shown in Figure 2-5, and can result from input noise and
truncation. Nonlinearities can be eliminated using the QUANTA, QUANTB,and QUANTC variables.
Figure 2-5: Non-Linearity Caused by Quantification Noise
The error can be seen as the presence of a virtual constant noise current. While 10mA hardly contribute any er-
ror at currents of 10A and above, the noise becomes dominant at small currents.
0
2
4
6
8
10
12
0.1 110 100
I [A]
error [%]
error
71M6543 Demo Board User’s Manual
Page: 43 of 91 v5
The value to be used for QUANT can be determined by the following formula:
LSBIMAXVMAX
IV
error
QUANT ⋅⋅
⋅
−= 100
Where error = observed error at a given voltage (V) and current (I),
VMAX = voltage scaling factor, as described in section 1.8.3,
IMAX = current scaling factor, as described in section 1.8.3,
LSB = QUANT LSB value = 7.4162*10-10W
Example: Assuming an observed error as in Figure 2-5, we determine the error at 1A to be +1%. If VMAX is
600V and IMAX = 208A, and if the measurement was taken at 240V, we determine QUANTn as follows:
11339
104162.7208600
1240
100
1
10 −=
⋅⋅⋅
⋅
−= −
QUANT
There is a QUANTn register for each phase, and the values are to be written to the CE locations 0x28, 0x2C, or
0x30. It does not matter which current value is chosen as long as the corresponding error value is significant
(5% error at 0.2A used in the above equation will produce the same result for QUANTn).
Input noise and truncation can cause similar errors in the VAR calculation that can be eliminated using the
QUANT_VARn variables. QUANT_VARn is determined using the same formula as QUANT.
2.3 TEMPERATURE COMPENSATION
2.3.1 ERROR SOURCES
This section discussed the temperature compensation for meters equipped with 71M6xxx Remote Sensor Inter-
faces. Compensation for CT-based systems is much simpler, since the error sources are only the reference
voltage, the burden resistor, and the voltage dividers.
For a meter to be accurate over temperature, the following major sources of error have to be addressed:
1) The resistance of the shunt sensor(s) over temperature. The temperature coefficient (TC) of a shunt
resistor is typically positive (PTC) and can be far higher than the TC of the pure Manganin material
used in the shunt. TCs of several hundred PPM/°C have been observed for certain shunt resistors. A
shunt resistor with +100 PPM/°C will increase its resistance by 60°C * 100*10-6 PPM/°C, or +0.6%
when heated up from room temperature to +85°C, causing a relative error of +0.6% in the current
reading. This makes the shunt the most pronounced influence on the temperature characteristics of
the meter.
Typically, the TC of shunt resistors is mostly linear over the industrial temperature range and can be
compensated, granted the shunt resistor is at the same temperature as the on-chip temperature sen-
sors on the 71M6x0x Remote Sensor Interface IC or the 71M6543.
Generally, the lower the TC of a shunt resistor, the better it can be compensated. Shunts with high
TCs require more accurate temperature measurements than those with low TCs. For example, if a
shunt with 200 PPM/°C is used, and the temperature sensor available to the 71M6543 is only accurate
to ±3°C, the compensation can be inaccurate by as much as 3°C*200PPM/°C = 600 PPM, or 0.06%.
2) The reference voltage of the 71M6x03 Remote Sensor Interface IC. At the temperature extremes, this
voltage can deviate by a few mV from the room temperature voltage and can therefore contribute to
some temperature-related error. The TC of the reference voltage has both linear and quadratic com-
ponents (TC1 and TC2). Since the 71M6X03 Remote Interface IC has an on-chip temperature sensor,
and since the development of the reference voltage over temperature is predictable (to within ±10
PPM/°C for high-grade parts). For example, compensation of the current reading is possible for a part
with ±80 PPM°C to within ±60°C *80*10-6 PPM/°C, or ±0.48%.
The reference voltage can be approached by the nominal reference voltage:
VNOM(T) = VNOM(22)+(T-22)*TC1+(T-22)2*TC2
Actual values for TC1 and TC2 can be obtained using the formulae given in the data sheets for the
71M6543 and for the 71M6x03. Additionally, the Demo Code will automatically generate the compen-
sation coefficients based on TC1 and TC2 using the fuse values in each device.
71M6543 Demo Board User’s Manual
Page: 44 of 91 v5
3) The reference voltage of the 71M6543F IC. At the temperature extremes, this voltage can deviate by a
few mV from the room temperature voltage and can therefore contribute to some temperature-related
error, both for the current measurement (pins IAP and IAN) of the neutral current sensor (if used) and
for the voltage measurement (pin VA). As with the Remote Sensor Interface IC, the TC of the
71M6543F reference voltage has both linear and quadratic components. The reference voltage of the
71M6543F over temperature is predictable within ±40 PPM/°C, which means that compensation of the
current and voltage reading is possible to within ±0.24%.
The 71M6543H has more predictable temperature coefficients that allow compensation to within ±10
PPM/°C, resulting in ±0.06% inaccuracy.
The temperature coefficients of the reference voltage are published in the 71M6543F/H data sheet.
The Demo Code will automatically generate the compensation coefficients based on TC1 and TC2 us-
ing the fuse values in each device.
4) The voltage divider network (resistor ladder) on the Demo Board will also have a TC. Ideally, all resis-
tors of this network are of the same type so that temperature deviations are balanced out. However,
even in the best circumstances, there will be a residual TC from these components.
The error sources for a meter are summed up in Table 2-1.
Table 2-1: Temperature-Related Error Sources
Measured Item
Error Sources for Current
Error Sources for Voltage
Pins on 71M6543
Energy Reading
for phase A
VREF of 71M6xx3 for phase A 71M6543 VREF VA, ADC2/ADC3
(IBP/IBN)
Shunt resistor for phase A Voltage divider for VA
Energy Reading
for phase B
VREF of 71M6xx3 for phase B 71M6543 VREF VB, ADC4/ADC5)
ICP/ICN
Shunt resistor for phase B Voltage divider for VB
Energy Reading
for phase C
VREF of 71M6xx3 for phase C 71M6543 VREF VC, ADC6/ADC7
(IDP/IDN)
Shunt resistor for phase C Voltage divider for VC
Neutral Current
Reading
71M6543 VREF -- ADC0/ADC1
(IAP/IAN)
Sensor for neutral current --
When can summarize the thermal errors per phase n in the following equation:
( ) ( ) ( ) ( )
XSnXVDnnn CCCCIVP 64 1111 +⋅+⋅+⋅+⋅⋅=
The terms used in the above equation are defined as follows:
• Vn = voltage applied to the meter in phase n
• In = current applied to the shunt in phase n
• CVD = error contribution from the voltage divider
• C4X = error contribution from the voltage reference of the 71M6543
• CSn = error from the shunt resistor that is connected via the Remote Interface IC
• C6X = error contribution from the voltage reference of the Remote Interface IC
2.3.2 SOFTWARE FEATURES FOR TEMPERATURE COMPENSATION
In the default settings for the Demo Code, the CECONFIG register has its EXT_TEMP bit (bit 22) set, which
means that temperature compensation is performed by the MPU by controlling the GAIN_ADJ0 through
GAIN_ADJ, registers of the CE. Generally, these four (and when using neutral current measurement, five) reg-
isters are used as follows:
• GAIN_ADJ0 for VA, VB, VC – CE RAM 0x40
• GAIN_ADJ1 – Current, phase A (via 71M6xx3) – CE RAM 0x41
• GAIN_ADJ2 - Current, phase B (via 71M6xx3) – CE RAM 0x42
• GAIN_ADJ3 - Current, phase C (via 71M6xx3) – CE RAM 0x43
• GAIN_ADJ4 – Current from neutral current sensor (via 71M6543) – CE RAM 0x44
In general, the GAIN_ADJn registers offer a way of controlling the magnitude of the voltage and current signals
in the data flow of the CE code. A value of 16385 means that no adjustment is performed (unity gain), which
71M6543 Demo Board User’s Manual
Page: 45 of 91 v5
means that the output of the gain adjust function is the same as the input. A value of 99% of 16385, or 16222,
means that the signal is attenuated by 1%.
The Demo Code bases its adjustment on the deviation from calibration (room) temperature DELTA_T and the
coefficients PPMC and PPMC2 to implement the equation below:
23
2
14 2
2_
2
_
16385_ PPMCTDELTAPPMCTDELTA
ADJGAIN ⋅
+
⋅
+=
It can be seen easily that the gain will remain at 16385 (0x4001), or unity gain, when DELTA_T is zero. In the
Demo Code, DELTA_T is scaled so 0.1°C corresponds to 1 LSB of DELTA_T.
For complete compensation, the error sources for each channel have to be combined and curve-fit to generate
the PPMC and PPMC2 coefficients, as will be shown in the following section.
For Demo Codes revision 5.3a and later, the PPMC and PPMC2 coefficients are in the MPU RAM locations
listed in Table 2-3:
Table 2-2: MPU Registers for Temperature-Compensation
CE Lo-
cation
PPMC Register for CE Lo-
cation
PPMC2 Register for
0x20 GAIN_ADJ0 0x25 GAIN_ADJ0
0x21 GAIN_ADJ1 0x26 GAIN_ADJ1
0x22 GAIN_ADJ2 0x27 GAIN_ADJ2
0x23 GAIN_ADJ3 0x28 GAIN_ADJ3
0x24 GAIN_ADJ0 0x29 GAIN_ADJ0
When the Demo Code starts up (after reset or power-up), it determines whether the meter has been calibrated.
If this is not the case, the coefficients PPMC and PPMC2 are automatically determined based on information
found in the 71M6543 and in the 71M6x0x Remote Sensor Interface ICs. These coefficients are calculated to
compensate for the reference voltage deviation in these devices, but can be enhanced to also compensate for
the shunt resistors connected to each device.
2.3.3 CALCULATING PARAMETERS FOR COMPENSATION
2.3.3.1 Shunt Resistors
The TC of the shunt resistors can be characterized using a temperature chamber, a calibrated current, and a
voltmeter with filtering capabilities. A few shunt resistors should be measured and their TC should be compared.
This type of information can also be obtained from the manufacturer. For sufficient compensation, the TC of the
shunt resistors must be repeatable. If the shunts are the only temperature-dependent components in a meter,
and the accuracy is required to be within 0.5% over the industrial temperature range, the repeatability must be
better than:
R = (5000 PPM) / (60°C) = 83.3 PPM/°C
This means that for a shunt resistor with +200 PPM/°C, the individual samples must be within +116.7 PPM/°C
and 283.3 PPM/°C.
Let us assume a shunt resistor of 55 µΩ in phase A. This resistor is 10% above the nominal value of 50 µΩ, but
this is of minor importance, since this deviation will be compensated by calibration. In a temperature chamber,
this resistor generates a voltage drop of 5.4559 mV at -40°C and 5.541 mV at +85°C with a current of 100 A
applied. This is equivalent to a resistance deviation of 0.851 µΩ, or 15,473 PPM. With a temperature difference
between hottest and coldest measurement of 125°C, this results in +124 PPM/°C. At high temperatures, this re-
sistor will read the current 60°C * 124 PPM/°C, or 0.744% too high. This means that the GAIN_ADJ1 register
has to be adjusted by -0.744% at the same temperature to compensate for the TC of the shunt resistor.
71M6543 Demo Board User’s Manual
Page: 46 of 91 v5
Let us assume that only linear components appear in the formula below, i.e. PPMC2 is zero.
23
2
14 2
2_
2
_
16385_ PPMCTDELTAPPMCTDELTA
ADJGAIN ⋅
+
⋅
+=
We must now find the PPMC value that decreases GAIN_ADJ by 0.744% when DELTA_T is +600 (DELTA_T
is measured in tens of °C). We find PPMCS to be:
PPMCS = 214 * (16263 – 16385) / 600 = -3331
2.3.3.2 Remote Sensor Reference Voltage
The compensation coefficients for the reference voltage of the three 71M6103 are derived automatically by the
Demo Code. Typical coefficients are in the range of +500 to -300 for PPMC6X and -200 to -400 for PPMC26X.
2.3.3.3 Reference Voltage of the 71M6543 or 71M6543H
The compensation coefficients for the reference voltage of the 71M6543 are derived automatically by the Demo
Code. Typical coefficients are in the range of -200 to -400 for PPMC4X and -400 to -800 for PPMC24X.
2.3.3.4 Voltage Divider
In most cases, especially when identical resistor types are used for all resistors of the voltage divider ladder, the
TC of the voltage divider will be of minor influence on the TC of the meter.
If desired, the voltage divider can be characterized similar to the shunt resistor as shown above. The difference
is that there is no individual GAIN_ADJ for each voltage channel. GAIN_ADJ0 is primarily intended to compen-
sate for the temperature coefficients of the reference voltage. If the TC of the voltage dividers is to be consid-
ered, it has to be calculated based on the average error of each phase.
Let us assume, applying 240 Vrms to a meter and recording the RMS voltage displayed by the meter at -40°C,
room temperature, +55°C, and at +85°C (when averaged over all phases), we obtain the values in the center
column of Table 2-3.
Table 2-3: Temperature-Related Error Sources
Temperature [°C] Displayed Voltage Normalized Voltage
-40 246.48 240.458
25 246.01 240.0
55 245.78 239.78
85 245.56 239.57
After normalizing with the factor 240/246.01 to accommodate for the initial error, we obtain the values in the
third column. We determine the voltage deviation between highest and lowest temperature to be -0.88 V, which
is equivalent to -3671 PPM, or -29.4 PPM/°C.
For this, we obtain a PPMCVD value of 788.
2.3.3.5 Combining the Coefficients for Temperature Compensation
After characterizing all major contributors to the TC of the meter, we have all components at hand to design the
overall compensation. If we examine only phase A for the moment, we find that we will need the following coef-
ficients for the control of GAIN_ADJn:
CS1: The PPMCS = -3331 determined for the shunt resistor. PPMC2S for the shunt resistor is 0.
CVD: The PPMCVD value of 788 determined for the voltage divider.
C4X: PPMC4X = -820 and PPMC24X = -680
C6X: PPMC6X = -620 and PPMC26X = -510
We will find that coefficients can simply be added to combine the effects from several sources of temperature
dependence.
Following this procedure, we obtain the coefficients for GAIN_ADJ0 (voltage measurement) as follows:
• PPMCA = PPMC4X + PPMCVD = – 820 + 788 = -32
• PPMC2A = PPMC24X + PPMC2VD = -680 + 0 = -680
71M6543 Demo Board User’s Manual
Page: 47 of 91 v5
Next, we obtain the coefficients for GAIN_ADJ1 (current measurement) as follows:
• PPMCA = PPMCS + PPMC6X = -3331 - 620 = -3951
• PPMC2A = PPMC2S + PPMC26X = 0 - 510 = -510
Similar calculations apply to the remaining current phases.
2.3.3.6 Test Results for Temperature Compensation
Temperature tests were conducted that exercised the fuse accuracy in the 71M6xxx and 71M6543 in conjunc-
tion with the capability of the 654x Code to accurately read and interpret the fuses and to compensate the gain
in all measurement channels.
For these tests, three 50 µΩ shunts had been characterized, and coefficients combined from the shunt coeffi-
cients and the VREF coefficients for the 71M6543H and 71M6xxx had been generated and loaded into the
71M6543H. No compensation was used for the voltage divider in the 71M6543 Demo Board. The tests were
conducted with a 71M6543 Demo Board REV 3.0 populated with a 71M6543H and 3 x 71M6203 (dual-trim).
Figure 2-6 shows the results for the VREF compensation only (original coefficients obtained from fuses).
Figure 2-6: Wh Registration Error with VREF Compensation
Figure 2-7 shows the results for the combined compensation (original coefficients obtained from fuses com-
bined with shunt coefficients).
71M6543 Demo Board User’s Manual
Page: 48 of 91 v5
Figure 2-7: Wh Registration Error with Combined Compensation
2.4 TESTING THE DEMO BOARD
This section will explain how the 71M6543F IC and the peripherals can be tested. Hints given in this section will
help evaluating the features of the Demo Board and understanding the IC and its peripherals.
Demo Board. It interfaces to a PC through a 9 pin serial port connector.
It is recommended to set up the demo board with no live AC voltage connected, and to
connect live AC voltages only after the user is familiar with the demo system.
BEFORE CONNECTING THE DEMO BOARD TO A CALIBRATION SYSTEM OR OTHER
HIGH-VOLTAGE SOURCE IT IS RECOMMENDED TO MEASURE THE RESISTANCE BE-
TWEEN THE LINE AND THE NEUTRAL TERMINALS OF THE DEMO BOARD WITH A MULTI-
METER. ANY RESISTANCE BELOW THE 1 MΩ RANGE INDICATES A AFAULTY CONNEC-
TION RESULTING INDESTRUCTION OF THE 71M6543.
2.4.1 FUNCTIONAL METER TEST
This is the test that every Demo Board has to pass before being integrated into a Demo Kit. Before going into
the functional meter test, the Demo Board has already passed a series of bench-top tests, but the functional
meter test is the first test that applies realistic high voltages (and current signals from current transformers) to
the Demo Board.
Figure 2-8 shows a meter connected to a typical calibration system. The calibrator supplies calibrated voltage
and current signals to the meter. It should be noted that the current flows through the shunts or CTs that are not
part of the Demo Board. The Demo Board rather receives the voltage output signals from the current sensor. An
optical pickup senses the pulses emitted by the meter and reports them to the calibrator. Some calibration sys-
tems have electrical pickups. The calibrator measures the time between the pulses and compares it to the ex-
pected time, based on the meter Kh and the applied power.
71M6543 Demo Board User’s Manual
Page: 49 of 91 v5
Figure 2-8: Meter with Calibration System
Figure 2-9 shows the screen on the controlling PC for a typical Demo Board. The error numbers are given in
percent. This means that for the measured Demo Board, the sum of all errors resulting from tolerances of PCB
components, current sensors, and 71M6543F tolerances was –3.41%, a range that can easily be compensated
by calibration.
Figure 2-10 shows a load-line obtained with a 71M6543F. As can be seen, dynamic ranges of 200:0.25, or
1:800 for current can easily be achieved. Dynamic current ranges of 2,000:1 (0.1 A to 200 A) have been
achieved with 50 µΩ shunts mounted in ANSI enclosures.
Figure 2-9: Calibration System Screen
Calibrator
AC Voltage
Current CT
Meter
under
Test Optical Pickup
for Pulses
Calibrated
Outputs
Pulse
Counter
PC
71M6543 Demo Board User’s Manual
Page: 50 of 91 v5
Figure 2-10: Wh Load Lines at Room Temperature with 150 µΩ Shunts
Figure 2-11: VARh Load Lines at Room Temperature with 150 µΩ Shunts
2.4.2 EMC TEST
This Demo Board is not optimized for EMC. Please contact your Maxim representative or FAE for questions re-
garding EMC.
2.5 SENSORS AND SENSOR PLACEMENT
Both sensor self-heating and sensor placement have to be considered in order to avoid side effects that can af-
fect measurement accuracy. These considerations apply in general to both ANSI meters and IEC meters.
Both meter variations will be discussed below.
-0.5
-0.4
-0.3
-0.2
-0.1
0
0.1
0.2
0.3
0.4
0.5
0.1 110 100
0°
60°
Wh Poly-Phase Loadline with 150 µΩShunt
-0.5
-0.4
-0.3
-0.2
-0.1
0
0.1
0.2
0.3
0.4
0.5
0.1 110 100
90°
150°
VARh Poly-Phase Loadline with 150 µΩShunt
71M6543 Demo Board User’s Manual
Page: 51 of 91 v5
2.5.1 SELF-HEATING
The effect of self-heating will be most pronounced at maximum current and depends on the following parame-
ters:
• Nominal shunt resistance
• Current through the shunt resistor
• Thermal mass
• Heat conduction away from the shunt (thermal resistance towards the environment)
• Temperature coefficient of copper and resistive material.
It is quite obvious that the nominal resistance of the shunt resistor should be kept as low as possible. Table
1-10 shows a few combinations of shunt resistance and 71M6x0x part number. The parts with part numbers
corresponding to higher current capacity are designed to work with low shunt resistance. Lowering the shunt re-
sistance below the recommended limits decreases accuracy and repeatability.
Good heat conduction can help to maintain the shunt temperature. Attaching the shunt to solid metallic struc-
tures such as meter terminal blocks helps decreasing the thermal resistance. This, of course, applies to meters
where the terminals and other mechanical parts can be considered heat sinks, i.e. they do not heat up due to
other effects.
The thermal mass will control how long it takes the sensor to reach its maximum temperature. Meters, for which
only short-time maximum currents are applied, can benefit from a large thermal mass, since it will increase the
time constant of the temperature rise.
The temperature coefficient (TC) of the shunt is a very important factor for the self-heating effect. Shunts with a
TC of just a few PPM/°C can maintain good shunt accuracy even in the presence of significant self-heating.
There are several methods that can be applied in the meter design to minimize the effects of self-heating:
• Software algorithms emulating the thermal behavior of the shunt(s).
• Direct temperature measurement, ideally with the 71M6xx3 mounted directly on the shunt (collocation)
or employing some other method of temperature sensing (PTC resistor, NTC resistor, discrete temper-
ature sensor).
The effect of shunt self-heating can be described by the following formulae. First, the relative output of a shunt
resistor is:
ΔV/V = ΔR/R
ΔR is a function of the change in temperature, the temperature coefficient (TCR), the thermal resistance (RTH),
and, of course, the applied power, which is proportional to the square of the current:
RTH
R
TCRRI
R
TCTR
R
R
V
V⋅⋅=
⋅∆⋅
=
∆
=
∆
2
Ultimately, it is up to the meter designer to select the best combination of shunt resistance, TC, shunt geometry
and potential software algorithms for the given application.
2.5.2 PLACEMENT OF SENSORS (ANSI)
The arrangement of the current terminals in an ANSI meter enclosure predetermines shunt orientation, but it al-
so allows for ample space in between the sensors, which helps to minimize cross-talk between phases.
A good practice is to shape the shunts like blades and to place them upright so their surfaces are parallel. In an
ANSI-type 16S meter, the distance between the phase A sensor and the phase B sensor is roughly 25 mm,
which makes these two phases most critical for cross-talk. For the ANSI form 2S meter, which is a frequently
used single-phase configuration, the distance between the sensors is in the range of 70 mm, which makes this
configuration much less critical. However, even for this case, good sensor placement is essential to avoid cross-
talk.
Sensor wires should be tightly twisted to avoid loops that can be penetrated by the magnetic fields of the sen-
sors or conductors.
2.5.3 PLACEMENT OF SENSORS (IEC)
The arrangement of the current terminals in a typical IEC meter enclosure predetermines the spacing of the
shunts, and usually allows for only for 20 to 22 mm center-to-center spacing between the shunts. This means
that the clearance between adjacent shunts is typically only 10 mm or less. A typical arrangement is shown in
71M6543 Demo Board User’s Manual
Page: 52 of 91 v5
Figure 2-12, left side. This arrangement is not optimized for suppression of cross-talk, but it works well in most
cases.
If magnetic cross-talk between shunt sensors has to be minimized, the shunts may be arranged slightly different
from the standard configuration. An example with staggered shunt arrangement is shown in Figure 2-12, right
side. This illustration shows the shunts as seen from inside the meter, looking towards the terminal blocks. The
center shunt is lifted on spacers, which decouples the magnetic field lines.
Figure 2-12: Typical Sensor Arrangement (left), Alternative Arrangement (right)
Another possible arrangement is to swivel the shunts by 90°, as shown in Figure 2-13. This method is most ef-
fective at suppressing magnetic cross-talk, but requires more space in the meter enclosure.
Figure 2-13: Swiveled Sensor Arrangement
It is useful to minimize the loop area formed by the Manganin zone of the shunts and the wires. As with the AN-
SI sensors, it is recommended that sensor wires are tightly twisted to avoid loops that can be penetrated by the
magnetic fields of the sensors or conductors.
2.5.4 OTHER TECHNIQUES FOR AVOIDING MAGNETIC CROSSTALK
With very high currents or close distances between shunt sensors, magnetic pickup or cross-talk will sometimes
occur even if good placement practices are followed.
One mechanism for cross-talk is shown in Figure 2-14, where the Manganin zone and the sensor wire act as a
loop that will generate an output voltage similar to that generated by a Rogowski coil.
The effect of this loop can be compensated by adding a second loop on the opposite side of the shunt resistors,
as shown in Figure 2-15.
71M6543 Demo Board User’s Manual
Page: 53 of 91 v5
Figure 2-14: Loop Formed by Shunt and Sensor Wire
Figure 2-15: Shunt with Compensation Loop
Since the compensation loop is impractical, a similar compensation effect can be achieved by attaching the
sensor wires in the center, as shown in Figure 2-16. An economical approach to this technique is to drill holes in
the center of the shunt resistor for attachment of the sensor wires 1.
Figure 2-16: Shunt with Center Drill Holes
1 U.S. Pat. Pending
Loop Manganin
Copper
Sensor wires
Optional contact for
voltage
Symmetrical
loops
71M6543 Demo Board User’s Manual
Page: 54 of 91 v5
71M6543 Demo Board User’s Manual
Page: 55 of 91 v5
3 HARDWARE DESCRIPTION
3.1 71M6543 REV 4.0 DEMO BOARD DESCRIPTION: JUMPERS,
SWITCHES AND TEST POINTS
The items described in Table 3-1 refer to the flags in Figure 3-1.
Table 3-1: 71M6543 REV 4.0 Demo Board Description
Item # Reference
Designator Name Use
1 D5 Wh Wh pulse LED.
2 J1 PULSE X Y 3-pin header for monitoring X and Y pulses
3 JP2 BIT BANG 5-pin header for access to the SEGDIO4 and SEGDIO9
pins.
4 JP1 BAT MODE
Selector for the operation of the IC when main power is re-
moved, using the SEGDIO8 pin. A jumper across pins 2-3
(default) indicates that no external battery is available. The
IC will stay in brownout mode when the system power is
down and it will communicate at 9600bd. A jumper across
pins 1-2 indicates that an external battery is available. The
IC will be able to transition from brownout mode to sleep
and LCD modes when the system power is down.
5 JP55/JP52 --
JP55: 2-pin header for the SDATA signal used by the serial
EEPROM.
JP52: 2-pin header for the SDATA signal used by the
µWire EEPROM
6 U8 LCD 3-row LCD with 6 7-segment digits per row and special
metering symbols.
7 J19 SPI 2X5 header providing access to the SPI slave interface.
8 BT3 -- Alternate footprint for BT2. A circular battery may be
mounted in this location (on the bottom of the board).
9 BT1 -- Location of optional battery for the support of battery
modes. (Located on the bottom)
3
71M6543 Demo Board User’s Manual
Page: 56 of 91 v5
Item # Reference
Designator Name Use
10 BT2 --
Location of optional battery for the support of RTC and
non-volatile RAM. BT2 has an alternate circular footprint at
location BT3.
11 J21 DEBUG Connector for the optional Debug Board. 2x8 pin male
header.
12 SW5 RESET
Chip reset switch: When the switch is pressed, the RESET
pin of the IC is pulled high which resets the IC into a known
state.
13 J12 -- 2-pin header. If a jumper installed, the battery BT1 will be
connected to the V3P3SYS net.
14 J13 -- 2-pin pin header. If a jumper installed, the battery BT2/BT3
will be connected to the V3P3SYS net.
15 SW3 PB
Pushbutton connected to the PB pin on the IC. This push-
button can be used in conjunction with the Demo Code to
wake the IC from sleep mode or LCD mode to brown-out
mode.
16 TP2 GND GND test point.
17 J3 IAN_IN, IAP_IN
2-pin header for the connection of the non-isolated shunt
used for neutral current measurement. This header is on
the bottom of the board.
18 SW4 SEGDIO53 Pushbutton for optional software function.
18a J25 ADC0/1 2-pin header that allows access to the neutral current input
pins on the 71M6543.
19 JP6
A jumper is placed across JP6 to activate the internal AC
power supply.
Caution: High Voltage! Do not touch!
19a J11, J15, J16 ADC8, ADC9,
ADC10
2-pin headers that allow access to the voltage input pins on
the 71M6543.
20 J9 NEUTRAL
The NEUTRAL voltage input. This input is connected to
V3P3. This input is a spade terminal mounted on the bot-
tom of the board.
21, 23, 25 J4, J6. J8
VA_IN, VB_IN,
VC_IN
Phase voltage inputs to the board. Each input has a resis-
tor divider that leads to the pin on the IC associated with
the voltage input to the ADC. These inputs have spade
terminals mounted on the bottom of the board.
Caution: High Voltage! Do not touch!
22 TP1 TMUXOUT,
TMUX2OUT
Test points for access to the TMUXOUT and TMU2XOUT
pins on the 71M6543.
24 U5 -- The IC 71M6543 soldered to the PCB.
26, 28, 29 J17, J18, J20 -- Two-pin headers for connection of the external shunt resis-
tors (REV 4.0) or CTs (REV 5.0) to the board.
27 JP53 V3P3D
2-pin header that connects the V3P3D pin to parts on the
board that use the V3P3D net for their power supply. For
supply current measurements in brownout mode, the
jumper on JP53 may be removed.
29a J22, J23, J24 ADC2/3, ADC4/5,
ADC5/6
2-pin headers that allow access to the current input pins on
the 71M6543.
30 J14 EMULATOR I/F 2x10 emulator connector port for the Signum ICE ADM-51
or for the Teridian TFP-2 Flash Programmer.
31 JP3 ICE_E
3-pin header for the control of the ICE_E signal. A jumper
across pins 1-2 disables the ICE interface; a jumper across
pins 2-3 enables it.
71M6543 Demo Board User’s Manual
Page: 57 of 91 v5
Item # Reference
Designator Name Use
32 JP44 GND 3-pin header that can be used to control the PE pin of the
µWire EEPROM.
33 TP3 GND GND test point.
34 JP54 -- 2-pin header that connects the SDCK signal to the serial
EEPROM.
35 JP51 -- Two-pin header for the clock signal to the µWire EEPROM.
Inserting a jumper in this header enables the clock.
36 JP50 -- Two-pin header for pulling low the CS input of the µWire
EEPROM.
37 CN1 USB PORT This connector is an isolated USB port for serial communi-
cation with the 71M6543.
38 JP7 -- 2-pin header connected to the VARh pulse LED
39 D6 VARh VARh pulse LED.
40 JP8 WPULSE 2-pin header connected to the Wh pulse LED
41 JP5 UART_RX
2-pin header for connection of the RX output of the isolated
USB port to the RX pin of the 71M6543. When the Demo
Board is communicating via the USB port, a jumper should
be installed on JP5. When the Demo Board is communi-
cating via the Debug Board plugged into J21, the jumper
should be removed.
42 JP20 5.0 VDC Circular connector for supplying the board with DC power.
Do not exceed 5.0 VDC at this connector!
71M6543 Demo Board User’s Manual
Page: 58 of 91 v5
Figure 3-1: 71M6543 REV 4.0 Demo Board - Board Description
Default jumper settings are indicated in yellow. Elements shown in blue are on the bottom side of the board.
9
58
12
13
22 20
11
14
15
21
12674
3
16
18
19
27 26 23
10
252829
30
31
32
34
24
35
37
36
40
38
41
42
17
39
33
29a 19a
18a
71M6543 Demo Board User’s Manual
Page: 60 of 91 v5
3.3 BOARD HARDWARE SPECIFICATIONS
PCB Dimensions
Width, length 134 mm x 131 mm (5.276” x 5.157”)
Thickness 1.6mm (0.062”)
Height w/ components 40 mm (1.57”)
Environmental
Operating Temperature -40°…+85°C
Storage Temperature -40°C…+100°C
Power Supply
Using internal AC supply 100 V…240 V RMS
DC Input Voltage (powered from DC supply) 5.0 VDC ±0.3 V
Supply Current < 10 mA typical
Input Signal Range
AC Voltage Signal (VA, VB, VC) 0…240 V RMS
AC Current Signals (IA, IB, IC) from Shunt 0…19.64 mV RMS
AC Current Signals (IA, IB, IC) from CT 0…176.8 mV RMS
Interface Connectors
DC Supply (J20) Circular connector
Emulator (J14) 10x2 header, 0.05” pitch
Voltage Input Signals Spade terminals on PCB bottom
Current Input Signals 0.1” 1X2 headers on PCB bottom
USB port (PC Interface) USB connector
Debug Board (J2) 8x2 header, 0.1” pitch
SPI Interface 5x2 header, 0.1” pitch
Functional Specification
Program Memory 64 KB FLASH memory
NV memory 1Mbit serial EEPROM
Time Base Frequency 32.768kHz, ±20PPM at 25°C
Controls and Displays
RESET Push-button (SW5)
PB Push-button (SW3)
Numeric Display 3X8-digit LCD, 7 segments per digit, plus meter symbols
“Wh” red LED (D5)
“VARh” red LED (D6)
Measurement Range
Voltage 120…600 V rms (resistor division ratio 1:3,398)
Current Dependent on shunt resistance or CT winding ratio
71M6543 Demo Board User’s Manual
Page: 61 of 91 v5
4 APPENDIX
This appendix includes the following documentation, tables and drawings:
71M6543 Demo Board Description
71M6543 REV 4.0 Demo Board Electrical Schematic
71M6543 REV 4.0 Demo Board Bill of Materials
71M6543 REV 4.0 Demo Board PCB layers (copper, silk screen, top and bottom side)
Schematics comments
71M6543 REV 5.0 Demo Board Electrical Schematic
71M6543 REV 5.0 Demo Board Bill of Materials
71M6543 REV 5.0 Demo Board PCB layers (copper, silk screen, top and bottom side)
Debug Board Description
Debug Board Electrical Schematic
Debug Board Bill of Materials
Debug Board PCB layers (copper, silk screen, top and bottom side)
71M6543 IC Description
71M6543 Pin Description
71M6543 Pin-out
4
71M6543 Demo Board User’s Manual
Page: 62 of 91 v5
4.1 71M6543 DEMO BOARD REV 4.0 ELECTRICAL SCHEMATIC
Figure 4-1: Teridian 71M6543 REV 4.0 Demo Board: Electrical Schematic 1/4
Title
Size Document Number Rev
Date: Sheet of
D6540 4.0
71M6543 Meter Demo Board
B
2 5Friday , January 07, 2011
Pull JP53 for BRN
current measurements.
GND
TMUXOUT
TMUX2OUT
SEGDIO52
GND
UART_RX
V3P3SYS
SEGDIO4
GND
SEGDIO35
V3P3SYS
SEGDIO32
SEGDIO24
SPI_CK
+5V_USB
ICE_EN
GND
UART 1
GND
SEGDIO21
DIO5
SEGDIO33
SEGDIO13
SEGDIO22
GND
SEGDIO52
XPULSE
VARS
WATTS
V2P5
SEGDIO20
VBAT_RTC
V3P3SYS
VBAT
SEGDIO14
SEGDIO12
YPULSE
VPULSE
XTAL_GND
SEGDIO31
OPT_RX
ADC8
GND
GND
WPULSE
SEGDIO19
ADC2
SEGDIO34
GND
SEGDIO15
SEGDIO32
PULSE OUTPUTS
SEGDIO10
OPT_TX
XTAL_GND
SEGDIO18
TMUX2OU T
WPULSE
ADC9
SEGDIO8
V3P3SYS
GND_USB
GND_USB
ADC3
TX& R XL ED
+5V_USB GND_USB
RX_USB
SEGDIO33
ICE_EN
SEGDIO16
COM3
SEGDIO17
SEGDIO10
Note: Place
C24, C25, Y1
close to U5
GND
GND
TMUXOU T
VLCD
ICE_EN
VREF
COM4
SEGDIO34
VPULSE
SW3
R11 62
C26
0.1uF
J1
1
2
3
R142
10K
J19
HDR5X2
2
4
6
8
10
1
3
5
7
9
SEGDIO16
R17
62
ADC10
XI N
+C45
10uF
JP55
HDR2X1
1 2
C63
0.1uF
SEGDIO17
C60
0.1uF
R144
10K
C50
1000pF
R109
10K
R18
0
J21
HDR8X2
12
34
56
78
910
11 12
13 14
15 16
C59
100pF
ADC4
U8 LCD VLS-6648
COM3
1
COM4
2
COM5
3
X5,1E,1F,7F,13F,13E
4
FE,13G,13D
5
7D,13A,13C
6
7C,13B,DP13
7
7G,14F,14E
8
7B,14G,14D
9
7A,14A,14C
10
DP7,14B,DP14
11
8F,15F,15E
12
8E,15G,15D
13
8D,15A,15C
14
8C,15B,DP15
15
8G,16F,16E
16
8B,16G,16D
17
8A,16A,16C
18
DP8,16B,DP16
19
9F,17F,17E
20
9E,17G,17D
21
9D,17A,17C
22
9G,17B,DP17
23
9C,18F,18E
24
9A,18G,18D
25
X7,X8,X6,9B,18A,18C
26
DP9,18B,DP18
27
X15,10E,10F,X9,X16,X22
28 DP12,12C,12B,X11,X20,X19 29
12D,12G,12A 30
X14,12E,12F,X12,X21 31
DP11,11C,11B 32
11D,11G,11A 33
X13,11E,11F,X10,X17,X18 34
DP10,10C,10B 35
10D,10G,10A 36
DP6,6C,6B 37
6D,6G,6A 38
X1,6E,6F 39
DP5,5C,5B 40
5D,5G,5A 41
X2,5E,5F 42
DP4,4C,4B 43
4D,4G,4A 44
X3,4E,4F 45
DP3,3C,3B 46
3D,3G,3A 47
X4,3E,3F 48
DP0,2C,2B 49
2D,2G,2A 50
DP2,2E,2F 51
DP1,1C,1B 52
1D,1G,1A 53
COM2 54
COM1 55
COM0 56
J14
ICE Header
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
1920
R1
1K
R104
10K
JP3
1
2
3
R107
10K
C28
0.1uF
R15
62
+C47
10uF
C22
0.1uF
C49
1000pF
TP1
HDR2X1
1 2
COM5
R138
10K
R137
1K
V3P3SYS
J12
1
12
2
V3P3D
C57
1000pF
C73
4.7uF
Y1
32.768KHz
1 2
R103
10K
C64
0.1uF
R76
10K
C36
1000pF
V3P3D
R2
1K
SEGDIO23
C61
1000pF
R106
1K
CN1
USB-W
VBUS
1
D-
2
D+
3
GND
4
5
5
6
6
C43
1000pF
L16
Ferrite Bead 600ohm
SEGDIO15
SEGDIO44
+
BT2
BATTERY
JP53
HDR2X1
12
L1
Ferrite Bead 600ohm
C30
22pF
BT3
BATTERY
C52
1000pF
JP2
1
2
3
4
5
JP52
HDR2X1
12
C25
10pF
R74
10K
C70
0.1uF
SEGDIO25
C19
0.1uF
C3
0.1uF
JP8
HDR2X1
1 2
R108
10K
C1
1000pF
C21
0.1uF
R143
10K
R150
100
R12
100K
R13
100K
ADUM3201
U3
VDD1
1
VOA
2
VIB
3
GND1
4
VDD2 8
VIA 7
VOB 6
GND2 5
C18
0.1uF
C51
0.1uF
C24
15pF
C74
0.1uF
C72
0.01uF
R79
100
R19
1K
OPT_TX
JP51
HDR2X1
12
SW4
C20
0.1uF
TP2
1
R4
100
JP44
1
2
3
C71
0.1uF
JP45
1
2
3
COM4
J13
1
12
2
V3P3D
C55
100pF
TP3
1
D5
1 2
Q1
BP103
SDCK
JP54
HDR2X1
1 2
R10 62
SEGDIO40
UART_RX_ISO
SEGDIO14
GND_USB
JP5
HDR2X1
12
U9
SER EEPROM (uWire)
CS
1
CLK
2
DI
3
DO
4VSS 5
ORG 6
PE 7
VCC 8
D6
12
D10
LED
VBAT
C62
0.1uF
SEGDIO43
C77
0.1uF
+
BT1
BATTERY
GND
VLCD
R77
100K DNP
D7
LD274
12
C31
22pF
JP1
1
2
3
U2
FT232RQ
VCCIO
1
R XD
2
RI#
3
GND
4
NC
5
DSR#
6
DCD#
7
CTS#
8
CBUS4
9
CBUS2
10
CBUS3
11
NC
12
NC
13
USBDP
14
USBDM
15
3V3OUT
16
GND 17
RESET# 18
VCC 19
GND 20
CBUS1 21
CBUS0 22
NC 23
AGND 24
NC 25
TEST 26
OSCI 27
OSCO 28
NC 29
TXD 30
DTR# 31
RTS# 32
SLUG 33
R9 62
R151
10K
JP50
HDR2X1
12
SEGDIO9
SW5
R105
10K
COM5
U4
SER EEPROM
A0
1
A1
2
A2
3
GND
4SDA 5
SCL 6
WP 7
VCC 8
JP7
HDR2X1
1 2
R16
62
ADC1
V3P3SYS ADC3
ADC0
ADC5
ADC2
ADC8 ADC4
ADC10
ADC9
GND
ADC6
ADC7
GND
XPULSE
SEGDIO41
SEGDIO13
GND
COM0
SEGDIO18
SDATA
SEGDIO42
+5V_USB
ADC5
UAR T_TX
V3P3SYS
VBAT PB
VBAT_RTC
E_RXTX
SEGDIO35
V3P3D
SDCK
GND
UAR T_TX
TX_ U S B UART_RX_ISO
RX_USB
SEGDIO19
LCD
+5V_USB
GND_USB
V3P3SYS
SPI_CSZ
SEGDIO41
SEGDIO12
TMUX2OU T
V3P3D
GND
GND
SEGDIO54
SDCK
YPULSE
V3P3SYS
V3P3SYS
GND
GND
SPI_DO
XTAL_GND
V3P3D
SEGDIO28
GND
V3P3D
SEGDIO20
SEGDIO11
V3P3D
OPT_RX
ADC1
DIO4
SEGDIO40
GND
GND
UART_TX
GND
SPI_DI
SERIAL EEPROM
GND
V3P3SYS
SEGDIO29
OPT_RX
SEGDIO29
COM1
U5
71M6543-100TQFP
SPI_DI/SEGDIO38
1
SPI_DO/SEGDIO37
2
SPI_CSZ/SEGDIO36
3
SEGDIO35
4
SEGDIO34
5
SEGDIO33
6
SEGDIO32
7
SEGDIO31
8
SEGDIO30
9
SEGDIO29
10
SEGDIO28
11
COM0
12
COM1
13
COM2
14
COM3
15
SEGDIO27/COM4
16
SEGDIO26/COM5
17
SEGDIO25
18
SEGDIO24
19
SEGDIO23
20
SEGDIO22
21
SEGDIO21
22
SEGDIO20
23
SEGDIO19
24
SEGDIO18
25
NC 26
SEGDIO17 27
SEGDIO16 28
SEGDIO15 29
SEGDIO14 30
SEGDIO13 31
SEGDIO12 32
SEGDIO11 33
SEGDIO10 34
SEGDIO9 35
SEGDIO8 36
SEGDIO7 37
SEGDIO6 38
NC 40
SEGDIO4 41
SDATA 42
SDCK 43
VPULSE 44
WPULSE 45
OPT_RX/SEGDIO55 46
SEGDIO54 47
NC 48
NC 49
NC 50
SEGDIO53 51
SEGDIO52 52
OPT_TX/SEGDIO51 53
TX 54
RX 55
E_RST/SEG50 56
E_TCLK/SEG49 57
E_RXTX/SEG48 58
ICE_E 59
VDD 60
V3P3D 61
GNDD3 62
IADC7 63
IADC6 64
IADC5 65
IADC4 66
IADC3 67
IADC2 68
V3P3SYS 69
VBAT 70
VBAT_RTC 71
GNDA 72
NC 73
NC 74
XO U T
76
NC
77
NC
78
NC
79
GNDA_K
80
TEST
81
VADC10
82
VADC9
83
VADC8
84
V3P3A_K
85
IADC1
86
IADC0
87
VREF
88
VLCD
89
PB
90
RESET
91
TMUX2OUT/SEG46
93
SEGDIO45
94
SEGDIO44
95
SEGDIO43
96
SEGDIO42
97
SEGDIO41
98
SEGDIO40
99
SPI_CK/SEGDIO39
100
TMUXOUT/SEG47
92
SEGDIO5 39
XIN 75
ADC6
V3P3D
GND
SEGDIO21
GND_USB
E_RST
E_TCLK
SEGDIO8
E_TCLK
SEGDIO28
+5V
BIT BANG HDR
TMUXOU T
ADC0
V3P3SYS
USB Connector, straight
SEGDIO53
GND
COM2
OPT_TX
SEGDIO30
GND
SEGDIO54
E_RST
GND
SEGDIO30
E _R XT X
ADC7
SEGDIO22
GND
UART_RX
GND
SEGDIO25
EMULATOR I/F
GND
COM3
SEGDIO11
SDATA
SEGDIO20
SEGDIO21
SEGDIO18
SEGDIO32
SEGDIO19
SEGDIO31
COM0
SEGDIO33
SEGDIO17
SEGDIO44
SEGDIO15
SEGDIO34
COM1
SEGDIO16
SEGDIO40
SEGDIO14
SEGDIO43
COM2
SEGDIO11
SEGDIO12
SEGDIO42
SEGDIO13
SEGDIO22
SEGDIO25
SEGDIO30
SEGDIO29
SEGDIO35
SEGDIO24
SEGDIO31
GND
V3P3D
SPI_DO
SPI_CK
SPI_CSZ
SPI_DI
SEGDIO23
SEGDIO24
71M6543 Demo Board User’s Manual
Page: 63 of 91 v5
Figure 4-2: Teridian 71M6543 REV 4.0 Demo Board: Electrical Schematic 2/4
NEUTRAL
Fr om NEUTRA L
terminal.
V B_IN
NEUTRAL
V C_IN
NEUTRAL
5VDC
NEUTRAL
*
R6, R7, R8 can be used to
generate a virtual neutral.
V3P3SYS
VA_IN
L17
Ferrite Bead 600ohm
+C2
22uF
RV2
VARISTOR
12
D9
ES1J
C5
0.1uF
D12
S1J
D14
S1J
J4
11
R73
100
C44
1000pF
R110
2K
R20
8.06K
L18
Ferrite Bead 600ohm
R111
4.02K
C46
0.03 uF
12
R65
100
C54
0.1uF
DNP
R146
3.4K
D8
S1J
+C39
100uF
JP4
1
12
2
C53
1000pF
J6
11
+
C35
2.2uF
R8
75K
DNP
U1
TL431
RV3
VARISTOR
12
L8
180uH
R152
68
D13
S1J
R6
75K
DNP
U6
LNK304-TN
BP
1
FB
2
D
4S1 5
S2 6
S3 7
S4 8
R7
75K
DNP
+C7
10uF
R149
68
R21
25.5K
JP20
1
2
3
D17
1.5KE350A
JP6
1
12
2
R139
1.5
C42
1000pF
RV1
VARISTOR
12
R141
100
R147
3.4K
J8
11
+
C6
10uF
C27
0.1uF
R140
3.4K
R148
820
V3P3SYS
GND
VB_IN
VC_IN
NEUTRAL
VA_IN
VA_IN
NEUTRAL
GND
VB_IN
VC_IN
L_RECT
Title
Size Document Number Rev
Date: Sheet of
D6543 4.0
71M6543 Meter Demo Board
B
3 5Wednesday , December 15, 2010
71M6543 Demo Board User’s Manual
Page: 64 of 91 v5
Figure 4-3: Teridian 71M6543 REV 4.0 Demo Board: Electrical Schematic 3/4
U17
71M6103-8SOIC
VCC 1
SP 2
SN 3
GND 4
TMUX
5
INP
6
INN
7
TEST
8
U15
71M6103-8SOIC
VCC 1
SP 2
SN 3
GND 4
TMUX
5
INP
6
INN
7
TEST
8
U16
71M6103-8SOIC
VCC 1
SP 2
SN 3
GND 4
TMUX
5
INP
6
INN
7
TEST
8
R96
499
R93
499
R89 499
C37
1000pF
DNP
R94
499
R81
10K
R90 499
R25
3.4
100 PPM
ADC0
ADC1
C41
1000pF
DNP
C65
1000pF
C67
1000pF
IADC2/IADC3 PINS
Population options f or R29, R28, R24, etc.
w hen using CTs:
2 x 3.4 Ohm, 100 PPM - Vishay/Dale CRCW12063R40FKEA,
Digi-Key P/N 541-3.40FFCT-ND (1206), or
3 x 5.1 Ohm, 50 PPM - Vishay/Dale SMM02040C5108FB300,
Mouser P/N 71-SMM02040C5108FB30
C68
1000pF
R97, R92, R91, etc. are through-hole
1/8 W parts in order to provide enough
pin-to-pin distance to accommodate the
clearance and creepage required.
T5
750110056
1
6
34
L4
0 Ohm
C38
1000pF
DNP
INN_IN
INP_IN
L5
0 Ohm
GND
R30
3.4
DNP
100 PPM
R31
3.4
DNP
100 PPM
R91
0DNP
IADC4/IADC5 PINS
R100
0DNP
IADC6/IADC7 PINS
1.08 : 1
J23
11
22
V3P3SYS
R34
3.4
DNP
100 PPM
* *
T4
750110056
16
34
This channel used for Phase A sensors.
ADC5
GND_R6000_B
IACP/IAN PINS
ADC0/ADC1
IBP_IN
IBN_IN
IC_IN
C32
1000pF
DNP
This channel used for Phase C sensors.
* *
ADC4
Alternative footprint option for
Midcom 750110057 (8 kV) to
be provided on daughter boards.
This channel used for Phase B sensors.
R101
0DNP
IB
L6
0 Ohm
L7
0 Ohm
* *
IC
GND_R6000_A
IA P_IN
IA N_IN
IB_IN
C69
1000pF
Isolation Barrier
T6
750110056
16
34
GND
Population Options:
Part 71M6xxx CT Option
R26, R27 DNP 3.4 Ohm 1206 (100 PPM), or
R26,R27,R32 DNP 5.1 Ohm MELF (50 PPM)
R89, R90 499 Ohm 10 kOhm
R97, R92 DNP 750 Ohm
C48, C58 1,000pF 1,000 pF
R91 DNP 0 Ohm
U15 71M6103 DNP
T4 MidCom-56 DNP
C17 1 uF DNP
This channel used for NEUTRAL. No isolation, and no remote sensor.
R92
750 DNP
IN_IN
ADC3
R98
750 DNP
IA
Title
Size Document Number Rev
Date: Sheet of
D6543 4.0
71M6543 Meter Demo Board
B
4 5Thursday , January 06, 2011
R28
3.4
DNP
100 PPM
R29
3.4
DNP
100 PPM
ADC2
R97
750 DNP
R36
3.4
DNP
100 PPM
R35
3.4
DNP
100 PPM
R102
750 DNP
C48
1000pF
ADC7
R26
3.4
DNP
100 PPM
R27
3.4
DNP
100 PPM
C58
1000pF
J22
11
22
C29
1000pF
DNP
C40
1000pF
DNP
R112
750 DNP
ADC6
L10
0 Ohm
L9
0 Ohm
GND_R6000_C
R99
750 DNP
J24
11
22
R54
750
ICP_IN
ICN_IN
IA_IN
R82
10K
R24
3.4
100 PPM
J20
11
22
R14
750
C17
1uF
C8
1000pF
J17
11
22
C56
1uF
L2
0 Ohm
J25
11
22
L3
0 Ohm
C66
0.1uF
J18
11
22
J3
11
22
R95
499
C14
1000pF
R32
3.4
DNP
100 PPM
C34
1uF
71M6543 Demo Board User’s Manual
Page: 65 of 91 v5
Figure 4-4: Teridian 71M6543 REV 4.0 Demo Board: Electrical Schematic 4/4
GND
Title
Size Document Number Rev
Date: Sheet of
DB6543 4.0
<Title>
A
5 5Wednesday , December 15, 2010
V A DC8 PIN
V A DC9 PIN
V A DC10 PIN
R38
4.7K
R46
270K
R63
2M
R62
270K
J11
1
1
2
2
V3P3SYS
J16
1
1
2
2
J15
1
1
2
2
VC_IN
L11
Ferrite Bead 600ohm
L13
Ferrite Bead 600ohm
L12
Ferrite Bead 600ohm
C9
1000pF
R72
750
R47
270K
R39
4.7K
R66
2M
R64
270K
C11
1000pF
ADC10
C13
1000pF
ADC8
VA_IN
R33
750
VB_IN
R58
4.7K
ADC9
R60
270K
R59
270K
R52
750
R61
2M
ADC10
VC_IN
VA_IN
VB_IN
NEUTRA L
GND
C15
1000pF
VOLTAGE
CONNECTIONS
NEUTRAL
J9
11NEUTRAL
If high-precision Rs are not available, use:
Vishay P/N RN65D2004FB14
Mouser P/N 71-RN65D-F-2.0M
TC = 100 PPM/C
71M6543 Demo Board User’s Manual
Page: 66 of 91 v5
4.2 71M6543 DEMO BOARD REV 5.0 ELECTRICAL SCHEMATIC
Figure 4-5: Teridian 71M6543 REV 5.0 Demo Board: Electrical Schematic 1/4
Title
Size Document Number Rev
Date: Sheet of
D6540 5.0
71M6543 Meter Demo Board
B
1 3Friday , January 07, 2011
Pull JP53 for BRN
current measurements.
GND
TMUXOUT
TMUX2OUT
SEGDIO52
GND
UART_RX
V3P3SYS
SEGDIO4
GND
SEGDIO35
V3P3SYS
SEGDIO32
SEGDIO24
SPI_CK
+5V_USB
ICE_EN
GND
UART 1
GND
SEGDIO21
DIO5
SEGDIO33
SEGDIO13
SEGDIO22
GND
SEGDIO52
XPULSE
VARS
WATTS
V2P5
SEGDIO20
VBAT_RTC
V3P3SYS
VBAT
SEGDIO14
SEGDIO12
YPULSE
VPULSE
XTAL_GND
SEGDIO31
OPT_RX
ADC8
GND
GND
WPULSE
SEGDIO19
ADC2
SEGDIO34
GND
SEGDIO15
SEGDIO32
PULSE OUTPUTS
SEGDIO10
OPT_TX
XTAL_GND
SEGDIO18
TMUX2OU T
WPULSE
ADC9
SEGDIO8
V3P3SYS
GND_USB
GND_USB
ADC3
TX& R XL ED
+5V_USB GND_USB
RX_USB
SEGDIO33
ICE_EN
SEGDIO16
COM3
SEGDIO17
SEGDIO10
Note: Place
C24, C25, Y1
close to U5
GND
GND
TMUXOU T
VLCD
ICE_EN
VREF
COM4
SEGDIO34
VPULSE
SW3
R11 62
C26
0.1uF
J1
1
2
3
R142
10K
J19
HDR5X2
2
4
6
8
10
1
3
5
7
9
SEGDIO16
R17
62
ADC10
XI N
+C45
10uF
JP55
HDR2X1
1 2
C63
0.1uF
SEGDIO17
C60
0.1uF
R144
10K
C50
1000pF
R109
10K
R18
0
J21
HDR8X2
12
34
56
78
910
11 12
13 14
15 16
C59
100pF
ADC4
U8 LCD VLS-6648
COM3
1
COM4
2
COM5
3
X5,1E,1F,7F,13F,13E
4
FE,13G,13D
5
7D,13A,13C
6
7C,13B,DP13
7
7G,14F,14E
8
7B,14G,14D
9
7A,14A,14C
10
DP7,14B,DP14
11
8F,15F,15E
12
8E,15G,15D
13
8D,15A,15C
14
8C,15B,DP15
15
8G,16F,16E
16
8B,16G,16D
17
8A,16A,16C
18
DP8,16B,DP16
19
9F,17F,17E
20
9E,17G,17D
21
9D,17A,17C
22
9G,17B,DP17
23
9C,18F,18E
24
9A,18G,18D
25
X7,X8,X6,9B,18A,18C
26
DP9,18B,DP18
27
X15,10E,10F,X9,X16,X22
28 DP12,12C,12B,X11,X20,X19 29
12D,12G,12A 30
X14,12E,12F,X12,X21 31
DP11,11C,11B 32
11D,11G,11A 33
X13,11E,11F,X10,X17,X18 34
DP10,10C,10B 35
10D,10G,10A 36
DP6,6C,6B 37
6D,6G,6A 38
X1,6E,6F 39
DP5,5C,5B 40
5D,5G,5A 41
X2,5E,5F 42
DP4,4C,4B 43
4D,4G,4A 44
X3,4E,4F 45
DP3,3C,3B 46
3D,3G,3A 47
X4,3E,3F 48
DP0,2C,2B 49
2D,2G,2A 50
DP2,2E,2F 51
DP1,1C,1B 52
1D,1G,1A 53
COM2 54
COM1 55
COM0 56
J14
ICE Header
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
1920
R1
1K
R104
10K
JP3
1
2
3
R107
10K
C28
0.1uF
R15
62
+C47
10uF
C22
0.1uF
C49
1000pF
TP1
HDR2X1
1 2
COM5
R138
10K
R137
1K
V3P3SYS
J12
1
12
2
V3P3D
C57
1000pF
C73
4.7uF
Y1
32.768KHz
1 2
R103
10K
C64
0.1uF
R76
10K
C36
1000pF
V3P3D
R2
1K
SEGDIO23
C61
1000pF
R106
1K
CN1
USB-B
VBUS
1
D-
2
D+
3
GND
4
5
5
6
6
C43
1000pF
L16
Ferrite Bead 600ohm
SEGDIO15
SEGDIO44
+
BT2
BATTERY
JP53
HDR2X1
1 2
L1
Ferrite Bead 600ohm
C30
22pF
BT3
BATTERY
C52
1000pF
JP2
1
2
3
4
5
JP52
HDR2X1
1 2
C25
10pF
R74
10K
C70
0.1uF
SEGDIO25
C19
0.1uF
C3
0.1uF
JP8
HDR2X1
12
R108
10K
C1
1000pF
C21
0.1uF
R143
10K
R150
100
R12
100K
R13
100K
ADUM3201
U3
VDD1
1
VOA
2
VIB
3
GND1
4
VDD2 8
VIA 7
VOB 6
GND2 5
C18
0.1uF
C51
0.1uF
C24
15pF
C74
0.1uF
C72
0.01uF
R79
100
R19
1K
OPT_TX
JP51
HDR2X1
1 2
SW4
C20
0.1uF
TP2
1
R4
100
JP44
1
2
3
C71
0.1uF
JP45
1
2
3
COM4
J13
1
12
2
V3P3D
C55
100pF
TP3
1
D5
1 2
Q1
BP103
SDCK
JP54
HDR2X1
1 2
R10 62
SEGDIO40
UART_RX_ISO
SEGDIO14
GND_USB
JP5
HDR2X1
12
U9
SER EEPROM (uWire)
CS
1
CLK
2
DI
3
DO
4VSS 5
ORG 6
PE 7
VCC 8
D6
12
D10
LED
VBAT
C62
0.1uF
SEGDIO43
C77
0.1uF
+
BT1
BATTERY
GND
VLCD
R77
100K DNP
D7
LD274
12
C31
22pF
JP1
1
2
3
U2
FT232RQ
VCCIO
1
R XD
2
RI#
3
GND
4
NC
5
DSR#
6
DCD#
7
CTS#
8
CBUS4
9
CBUS2
10
CBUS3
11
NC
12
NC
13
USBDP
14
USBDM
15
3V3OUT
16
GND 17
RESET# 18
VCC 19
GND 20
CBUS1 21
CBUS0 22
NC 23
AGND 24
NC 25
TEST 26
OSCI 27
OSCO 28
NC 29
TXD 30
DTR# 31
RTS# 32
SLUG 33
R9 62
R151
10K
JP50
HDR2X1
1 2
SEGDIO9
SW5
R105
10K
COM5
U4
SER EEPROM
A0
1
A1
2
A2
3
GND
4SDA 5
SCL 6
WP 7
VCC 8
JP7
HDR2X1
1 2
R16
62
ADC1
V3P3SYS ADC3
ADC0
ADC5
ADC2
ADC8 ADC4
ADC10
ADC9
GND
ADC6
ADC7
GND
XPULSE
SEGDIO41
SEGDIO13
GND
COM0
SEGDIO18
SDATA
SEGDIO42
+5V_USB
ADC5
UAR T_TX
V3P3SYS
VBAT PB
VBAT_RTC
E_RXTX
SEGDIO35
V3P3D
SDCK
GND
UAR T_TX
TX_ U S B UART_RX_ISO
RX_USB
SEGDIO19
LCD
+5V_USB
GND_USB
V3P3SYS
SPI_CSZ
SEGDIO41
SEGDIO12
TMUX2OU T
V3P3D
GND
GND
SEGDIO54
SDCK
YPULSE
V3P3SYS
V3P3SYS
GND
GND
SPI_DO
XTAL_GND
V3P3D
SEGDIO28
GND
V3P3D
SEGDIO20
SEGDIO11
V3P3D
OPT_RX
ADC1
DIO4
SEGDIO40
GND
GND
UART_TX
GND
SPI_DI
SERIAL EEPROM
GND
V3P3SYS
SEGDIO29
OPT_RX
SEGDIO29
COM1
U5
71M6543-100TQFP
SPI_DI/SEGDIO38
1
SPI_DO/SEGDIO37
2
SPI_CSZ/SEGDIO36
3
SEGDIO35
4
SEGDIO34
5
SEGDIO33
6
SEGDIO32
7
SEGDIO31
8
SEGDIO30
9
SEGDIO29
10
SEGDIO28
11
COM0
12
COM1
13
COM2
14
COM3
15
SEGDIO27/COM4
16
SEGDIO26/COM5
17
SEGDIO25
18
SEGDIO24
19
SEGDIO23
20
SEGDIO22
21
SEGDIO21
22
SEGDIO20
23
SEGDIO19
24
SEGDIO18
25
NC 26
SEGDIO17 27
SEGDIO16 28
SEGDIO15 29
SEGDIO14 30
SEGDIO13 31
SEGDIO12 32
SEGDIO11 33
SEGDIO10 34
SEGDIO9 35
SEGDIO8 36
SEGDIO7 37
SEGDIO6 38
NC 40
SEGDIO4 41
SDATA 42
SDCK 43
VPULSE 44
WPULSE 45
OPT_RX/SEGDIO55 46
SEGDIO54 47
NC 48
NC 49
NC 50
SEGDIO53 51
SEGDIO52 52
OPT_TX/SEGDIO51 53
TX 54
RX 55
E_RST/SEG50 56
E_TCLK/SEG49 57
E_RXTX/SEG48 58
ICE_E 59
VDD 60
V3P3D 61
GNDD3 62
IADC7 63
IADC6 64
IADC5 65
IADC4 66
IADC3 67
IADC2 68
V3P3SYS 69
VBAT 70
VBAT_RTC 71
GNDA 72
NC 73
NC 74
XO U T
76
NC
77
NC
78
NC
79
GNDA_K
80
TEST
81
VADC10
82
VADC9
83
VADC8
84
V3P3A_K
85
IADC1
86
IADC0
87
VREF
88
VLCD
89
PB
90
RESET
91
TMUX2OUT/SEG46
93
SEGDIO45
94
SEGDIO44
95
SEGDIO43
96
SEGDIO42
97
SEGDIO41
98
SEGDIO40
99
SPI_CK/SEGDIO39
100
TMUXOUT/SEG47
92
SEGDIO5 39
XIN 75
ADC6
V3P3D
GND
SEGDIO21
GND_USB
E_RST
E_TCLK
SEGDIO8
E_TCLK
SEGDIO28
+5V
BIT BANG HDR
TMUXOU T
ADC0
V3P3SYS
USB Connector, straight
SEGDIO53
GND
COM2
OPT_TX
SEGDIO30
GND
SEGDIO54
E_RST
GND
SEGDIO30
E _R XT X
ADC7
SEGDIO22
GND
UART_RX
GND
SEGDIO25
EMULATOR I/F
GND
COM3
SEGDIO11
SDATA
SEGDIO20
SEGDIO21
SEGDIO18
SEGDIO32
SEGDIO19
SEGDIO31
COM0
SEGDIO33
SEGDIO17
SEGDIO44
SEGDIO15
SEGDIO34
COM1
SEGDIO16
SEGDIO40
SEGDIO14
SEGDIO43
COM2
SEGDIO11
SEGDIO12
SEGDIO42
SEGDIO13
SEGDIO22
SEGDIO25
SEGDIO30
SEGDIO29
SEGDIO35
SEGDIO24
SEGDIO31
GND
V3P3D
SPI_DO
SPI_CK
SPI_CSZ
SPI_DI
SEGDIO23
SEGDIO24
71M6543 Demo Board User’s Manual
Page: 67 of 91 v5
Figure 4-6: Teridian 71M6543 REV 5.0 Demo Board: Electrical Schematic 2/4
NEUTRAL
Fr om NEUTRA L
terminal.
V B_IN
NEUTRAL
V C_IN
NEUTRAL
5VDC
NEUTRAL
*
R6, R7, R8 can be used to
generate a virtual neutral.
V3P3SYS
VA_IN
L17
Ferrite Bead 600ohm
+C2
22uF
RV2
VARISTOR
12
D9
ES1J
C5
0.1uF
D12
S1J
D14
S1J
J4
11
R73
100
C44
1000pF
R110
2K
R20
8.06K
L18
Ferrite Bead 600ohm
R111
4.02K
C46
0.03 uF
12
R65
100
C54
0.1uF
DNP
R146
3.4K
D8
S1J
+C39
100uF
JP4
1
12
2
C53
1000pF
J6
11
+
C35
2.2uF
R8
75K
DNP
U1
TL431
RV3
VARISTOR
12
L8
180uH
R152
68
D13
S1J
R6
75K
DNP
U6
LNK304-TN
BP
1
FB
2
D
4S1 5
S2 6
S3 7
S4 8
R7
75K
DNP
+C7
10uF
R149
68
R21
25.5K
JP20
1
2
3
D17
1.5KE350A
JP6
1
12
2
R139
1.5
C42
1000pF
RV1
VARISTOR
12
R141
100
R147
3.4K
J8
11
+
C6
10uF
C27
0.1uF
R140
3.4K
R148
820
V3P3SYS
GND
VB_IN
VC_IN
NEUTRAL
VA_IN
VA_IN
NEUTRAL
GND
VB_IN
VC_IN
L_RECT
Title
Size Document Number Rev
Date: Sheet of
D6543 5.0
71M6543 Meter Demo Board
B
2 3Thursday , December 09, 2010
71M6543 Demo Board User’s Manual
Page: 68 of 91 v5
Figure 4-7: Teridian 71M6543 REV 5.0 Demo Board: Electrical Schematic 3/4
U17
71M6103-8SOIC
DNP
VCC 1
SP 2
SN 3
GND 4
TMUX
5
INP
6
INN
7
TEST
8
U15
71M6103-8SOIC
DNP
VCC 1
SP 2
SN 3
GND 4
TMUX
5
INP
6
INN
7
TEST
8
U16
71M6103-8SOIC
DNP
VCC 1
SP 2
SN 3
GND 4
TMUX
5
INP
6
INN
7
TEST
8
R96
10K
R93
10K
R89 10K
C37
1000pF
R94
10K
R81
10K
R90 10K
R25
5.1
50 PPM
ADC0
ADC1
C41
1000pF
C65
1000pF
DNP
C67
1000pF
DNP
IADC2/IADC3 PINS
Population options f or R29, R28, R24, etc.
w hen using CTs:
2 x 3.4 Ohm, 100 PPM - Vishay/Dale CRCW12063R40FKEA,
Digi-Key P/N 541-3.40FFCT-ND (1206), or
3 x 5.1 Ohm, 50 PPM - Vishay/Dale SMM02040C5108FB300,
Mouser P/N 71-SMM02040C5108FB30
C68
1000pF
DNP
R97, R92, R91, etc. are through-hole
1/8 W parts in order to provide enough
pin-to-pin distance to accommodate the
clearance and creepage required.
T5
750110056
DNP
1
6
34
L4
0 Ohm
C38
1000pF
INN_IN
INP_IN
L5
0 Ohm
GND
R30
5.1
50 PPM
R31
5.1
50 PPM
R91
0
IADC4/IADC5 PINS
R100
0
IADC6/IADC7 PINS
1.08 : 1
J23
11
22
V3P3SYS
V3P3SYS
R34
5.1
50 PPM
* *
T4
750110056
DNP
16
34
This channel used for Phase A sensors.
ADC5
GND_R6000_B
IACP/IAN PINS
ADC0/ADC1
IBP_IN
IBN_IN
IC_IN
C32
1000pF
This channel used for Phase C sensors.
* *
ADC4
Alternative footprint option for
Midcom 750110057 (8 kV) to
be provided on daughter boards.
This channel used for Phase B sensors.
R101
0
IB
L6
0 Ohm
L7
0 Ohm
* *
IC
GND_R6000_A
IA P_IN
IA N_IN
IB_IN
C69
1000pF
DNP
Isolation Barrier
T6
750110056
DNP
16
34
GND
Population Options:
Part 71M6xxx CT Option
R26, R27 DNP 3.4 Ohm 1206 (100 PPM), or
R26,R27,R32 DNP 5.1 Ohm MELF (50 PPM)
R89, R90 499 Ohm 10 kOhm
R97, R92 DNP 750 Ohm
C48, C58 DNP 1,000 pF
C29, C32 DNP 1,000 pF
R91 DNP 0 Ohm
U15 71M6xxx DNP
T4 MidCom - 56 DNP
C17 1 uF DNP
L9, L10 0 Ohm 600 Ohm ferrite
This channel used for NEUTRAL. No isolation, and no remote sensor.
R92
750
IN_IN
ADC3
R98
750
IA
Title
Size Document Number Rev
Date: Sheet of
D6543 5.0
71M6543 Meter Demo Board
B
3 3Thursday , March 24, 2011
R28
5.1
50 PPM
R29
5.1
50 PPM
ADC2
R97
750
R36
5.1
50 PPM
R35
5.1
50 PPM
R102
750
C48
1000pF
DNP
ADC7
R26
5.1
50 PPM
R27
5.1
50 PPM
C58
1000pF
DNP
J22
11
22
C29
1000pF
C40
1000pF
R112
750
ADC6
L10
0 Ohm
L9
0 Ohm
GND_R6000_C
R99
750
J24
11
22
R54
750
ICP_IN
ICN_IN
IA_IN
R82
10K
R24
5.1
50 PPM
J20
11
22
R14
750
C17
1uF
DNP
C8
1000pF
J17
11
22
C56
1uF
DNP
L2
0 Ohm
J25
11
22
L3
0 Ohm
C66
0.1uF
J18
11
22
J3
11
22
R95
10K
C14
1000pF
R32
5.1
50 PPM
C34
1uF
DNP
71M6543 Demo Board User’s Manual
Page: 69 of 91 v5
Figure 4-8: Teridian 71M6543 REV 5.0 Demo Board: Electrical Schematic 4/4
TC = 100 PPM/C
All Susumu resistors: TC = 25 PPM/C
GND
Title
Size Document Number Rev
Date: Sheet of
DB6543 5.0
<Title>
A
1 1Friday , January 07, 2011
V A DC8 PIN
V A DC9 PIN
V A DC10 PIN
R38
4.7K
R46
270K
R63
2M
R62
270K
J11
1
1
2
2
V3P3SYS
J16
1
1
2
2
J15
1
1
2
2
VC_IN
L11
Ferrite Bead 600ohm
L13
Ferrite Bead 600ohm
L12
Ferrite Bead 600ohm
C9
1000pF
R72
750
R47
270K
R39
4.7K
R66
2M
R64
270K
C11
1000pF
ADC10
C13
1000pF
ADC8
VA_IN
R33
750
VB_IN
R58
4.7K
ADC9
R60
270K
R59
270K
R52
750
R61
2M
ADC10
VC_IN
VA_IN
VB_IN
NEUTRA L
GND
C15
1000pF
VOLTAGE
CONNECTIONS
NEUTRAL
J9
11NEUTRAL
If high-precision Rs are not available, use:
Vishay P/N RN65D2004FB14
Mouser P/N 71-RN65D-F-2.0M
TC = 100 PPM/C
71M6543 Demo Board User’s Manual
Page: 70 of 91 v5
4.3 COMMENTS ON SCHEMATICS
4.3.1 GENERAL
The schematics shown in this document are provided for a Demo Meter that functions under laboratory conditions.
Maxim does not guarantee proper function of a meter under field conditions when using the Demo Board schematics.
Care should be taken by the meter designer that all applicable design rules as well as reliability, safety and legal
regulations are met by the meter design.
4.3.2 USING FERRITES IN THE SHUNT SENSOR INPUTS
The 71M6543 Demo Board in shunt configuration has footprints on the PCB to accommodate ferrites between the
shunt signal inputs and the 71M6xxxx Remote Sensors. These footprints, labeled L4, L5, L6, L7, L9, and L10, are
populated with 0-Ohm resistors. It is not advisable to directly replace these resistors with ferrites without further
changes, since this will degrade the low-current accuracy to some degree.
If ferrites are needed for EMC reasons, the input circuit should be modified as shown in Figure 4-9. The modifications
are as follows:
• Positions L4, L5, L6, etc. are replaced with ferrites.
• A 10Ω resistor is added across the sensor input.
• The two 1,000 pF capacitors from INP to local ground and from INN to local ground are replaced with
10,000 pF or higher value capacitors.
Figure 4-9: Input Circuit with Ferrites
R51
10.0
U19
71M6103-8SOIC
VCC 1
SP 2
SN 3
GND 4
TMUX
5
INP
6
INN
7
TEST
8
R115 499
R117 499
R118
0DNP
1.08 : 1
* *
T8
750110056
16
34
GND_R6000_A
IA P_IN
IA N_IN
R121
750 DNP IA
R123
750 DNP
C83
10,000pF
R49
3.4
DNP
C84
10,000pF
R50
3.4
DNP
L22
600 Ohm f errite
L21
600 Ohm f errite
IA_IN J30
11
22
C23
1uF
R53
3.4
DNP
71M6543 Demo Board User’s Manual
Page: 71 of 91 v5
4.4 71M6543 DEMO BOARD REV 4.0 BILL OF MATERIAL
Table 4-1: 71M6543 REV 4.0 Demo Board: Bill of Material (1/2)
Item QReference Part Footprint Digi-Key P/N Mous er P/N Manufacturer Manufacturer P/N Tol Rating HDR DNP
1 2 BT1 ,BT2 BATTERY
BAT 3 PIN
BARREL
COMBO
DNP
2 1 BT3 BATTERY
BAT CR2032
MAX
DNP
3 1 CN1 USB-W
USBV
806-KUSBVX-
BS1N-W
Kycon KUSBVX-BS1N-W
423 C1,C8,C9,C11,C13,C14,C15, 1000pF
603 445-1298-1-ND TDK C1608X7R2A102K 10% 100V
C36,C42,C43,C44,C48,C49,
C50,C52,C53,C57,C58,C61,
C65,C67,C68,C69
5 1 C2 22uF
SM/CT_3216 478-1663-1-ND AVX TAJA226K010RNJ 10% 10V
618 C3,C5,C18,C19,C20,C21, 0.1uF
603 445-1314-1-ND TDK C1608X7R1H104K 0.1 50V
C22,C26,C27,C28,C51,C60,
C62,C63,C64,C66,C74,C77
7 4 C6,C7,C45,C47 10uF
SM/CT_3216 478-1654-1-ND AVX TAJA106K010R 0.1 10V
8 3 C17,C34,C56 1uF
603 445-1604-1-ND TDK C1608X7R1C105K 10% 16V
9 1 C24 15pF
603 445-1271-1-ND TDK C1608C0G1H150J 5% 50V
10 1C25 10pF
603 445-1269-1-ND TDK C1608C0G1H100D 5% 50V
11 6C29,C32,C37,C38,C40,C41 1000pF
603 445-1298-1-ND TDK C1608X7R2A102K 10% 100V DNP
12 2C30,C31 22pF
603 445-1273-1-ND TDK C1608C0G1H220J 0.05 50V
13 1C35 2.2uF
CYL/D.400/LS.
200/.034
493-1227-ND Nichicon UVR2G2R2MPD 400V
14 1C39 100uF
CYL/D.400/LS.
200/.034
P963-ND Panasonic ECE-A1AKS101 20% 10V
15 1C46 0.03 uF
HIGH VOLT
DISC CAP
75-125LS30-R Vishay/BC 125LS30-R 1000V
16 1C54 0.1uF
603 445-1314-1-ND TDK C1608X7R1H104K 0.1 50V DNP
17 2C55,C59 100pF
603 445-1281-1-ND TDK C1608C0G1H101J 5% 50V
18 2C70,C71 0.1uF
805 478-3351-1-ND
AVX Corporatio
08055C104MAT2A 20% 50V
19 1C72 0.01uF
603 478-1227-1-ND
AVX Corporatio
06035C103KAT2A 0.1 50V
20 1C73 4.7uF
805 587-1782-1-ND Taiyo Yuden TMK212BJ475KG-T 0.1 25V
21 2D5,D6 LED_1
LED6513 67-1612-ND Lumex SSL-LX5093SRC/E
22 1D7 LD274
LED6513 475-1461-ND Osra m SFH 4511
23 4D8,D12,D13,D14 S1J
SMA/DIODE S1J -E3/61TGICT-ND
Vishay/Genera
S1J-E3/61T
24 1D9 ES1J
SMA/DIODE ES1JFSCT-ND Vishay ES1J
25 1D10 LED
805 L62415CT-ND CML CMD17-21UGC/TR8
26 1D17 1.5KE350A
DO-41 1.5KE350CALFCT-ND Littelfuse 1.5KE350CA
27 5JP1,J1,JP3,JP44,JP45 HDR3X1
BLKCON.100/V
H/TM1SQ/W.1
00/3
S1011E-36-ND Sullins PBC36SAAN 0.1
28 1JP2 HDR5X1
BLKCON.100/V
H/TM1SQ/W.1
00/5
S1011E-36-ND Sullins PBC36SAAN 0.2
29 25 TP1,J3,JP4,JP5,JP6,JP7, HDR2X1
BLKCON.100/V
H/TM1SQ/W.1
00/2
S1011E-36-ND Sullins PBC36SAAN 0.1
JP8,J11,J12,J13,J15,J16,
J17,J18,J20,J22,J23,J24,
J25,JP50,JP51,JP52,JP53,
JP54,JP55
30 1JP20 SWITCHCRAFT
SWITCHCRAFT SC237-ND
Switchcraft Inc.
RAPC712X
31 4J4,J6,J8,J9 Spade Terminal
FASTON A24747CT-ND Tyco/AMP 62395-1
32 1J14 ICE Header
RIBBON6513O
UTLINE
A33555-ND
571-5-104068-
1
Tyco/AMP 5-104068-1
33 1J19 HDR5X2
BLKCON.100/V
H/TM2OE/W.2
00/10
S2011E-36-ND Sullins PBC36DAAN 0.2
34 1J21 HDR8X2
BLKCON.100/V
H/TM2OE/W.2
00/16
S2011E-36-ND Sullins PBC36DAAN 0.3
35 7L1,L11,L12,L13,L16,L17,
Ferrite Bead 600oh
805 445-1556-1-ND TDK MMZ2012S601A 0.5A
L18
36 8L2,L3,L4,L5,L6,L7,L9,L10 0 Ohm
805 RMCF0805ZT0R00CT-ND Stackpole RMCF0805ZT0R00 0.5A
37 1L8 180uH
RFB0807 CoilCraft RFB0807-181L
38 1Q1 BP103
LED6513 475-1437-ND Osra m SFH 300-3/4 DNP
39 3RV1,RV2,RV3 VARISTOR
MOV CPS
2381594
594-2381-594-
55116
AVX 2381 594 55116
71M6543 Demo Board User’s Manual
Page: 72 of 91 v5
Table 4-2: 71M6543 REV 4.0 Demo Board: Bill of Material (2/2)
Item QReference Part Footprint Digi-Key P/N Mous er P/N Manufacturer Manufacturer P/N Tol Rating HDR DNP
40 2R1,R2 1K
805 541-1.0KACT-ND Vishay/Dale CRCW08051K00JNEA 5%
0.125W
41 1R4 100
805 541-100ACT-ND Vishay/Dale CRCW0805100RJNEA 5%
0.125W
42 3R6,R7,R8 75K
AXLE FLAME
UPRIGHT
75KW-2-ND Yageo RSF200JB-75K 5% 2W DNP
43 6R9,R10,R11,R15,R16,R17 62
603 P62GCT-ND Panasonic ERJ-3GEYJ620V 5% 0.1W
44 2R12,R13 100K
603 P100KGCT-ND Panasonic ERJ-3GEYJ104V 5% 0.1W
45 5R14,R33,R52,R54,R72 750
805 RR12P750DCT-ND Susumu RR1220P-751-D 0.01 0.1W
46 1R18 0
1206 RHM0.0ECT-ND
Rohm Semicond
MCR18EZHJ000 0.05 0.25W
47 3R19,R106,R137 1K
603 P1.00KHCT-ND Panasonic ERJ-3EKF1001V 1% 0.1W
48 1R20 8.06K
805 RHM8.06KCCT-ND Rohm MCR10EZHF8061 1%
0.125W
49 1R21 25.5K
805 P25.5KCCT-ND Panasonic ERJ-6ENF2552V 1%
0.125W
50 2R24,R25 3.4
1206 541-3.40FFCT-ND Vishay/Dale CRCW08053R40FNEA 1%
0.125W
51 10 R26,R27,R28,R29,R30,R31, 3.4
1206 541-3.40FFCT-ND Vishay/Dale CRCW08053R40FNEA 0.01
0.125W
DNP
R32,R34,R35,R36
52 3R38,R39,R58 4.7K
805 RG20P4.7KBCT-ND TDK RG2012P-472-B-T5 0%
0.125W
53 6R46,R47,R59,R60,R62,R64 270K
805 RG20P270KBCT-ND Susumu RG2012P-274-B-T5 0%
0.125W
54 3R61,R63,R66 2M
AXLE FLAME
UPRIGHT
71-RN65D-F-
2.0M
Vishay/Dale RN65D2004FB14 0.01 0.5W
55 3R65,R73,R141 100
AXLE FLAME
UPRIGHT
100W-2-ND Ya geo RSF200JB-100R 5% 2W
56 5R74,R103,R109,R142,R144 10K
603 P10.0KHCT-ND Panasonic ERJ-3EKF1002V 0.01 0.1W
57 8R76,R81,R82,R104,R105, 10K
805 541-10KACT-ND Vishay/Dale CRCW080510K0JNEA 5%
0.125W
R107,R108,R151
58 1R77 100K
603 541-10KACT-ND Panasonic ERJ-3GEYJ104V 5% 0.1W DNP
59 2R79,R150 100
603 P100GCT-ND Panasonic ERJ-3GEYJ101V 5% 0.1W
60 6R89,R90,R93,R94,R95,R96 499
603 P499HCT-ND Panasonic ERJ-3EKF4990V 1% 0.1W
61 3R91,R100,R101 0
RES_TH_50 0 0.0EBK-ND Yageo ZOR-12-B-52 1% 0.1W DNP
62 6R92,R97,R98,R99,R102, 750
RES_TH_50 0 270-750-RC Xicon 270-750-RC 1% 0.1W DNP
R112
63 1R110 2K
603 P2.00KHCT-ND Panasonic ERJ-3EKF2001V 1% 0.1W
64 1R111 4.02K
603 P4.02KHCT-ND Panasonic ERJ-3EKF4021V 1% 0.1W
65 2R138,R143 10K
603 P10.0KHCT-ND Panasonic ERJ-3EKF1002V 1% 0.1W DNP
66 1R139 1.5
1206 541-1.5ECT-ND Vishay/Dale CRCW12061R50JNEA 5% 0.25W
67 3R140,R146,R147 3.4K
805 541-3.40KCCT-ND Vishay/Dale CRCW08053K40FKEA 1%
0.125W
68 1R148 820
AXLE FLAME
UPRIGHT
P820W-2BK-ND Panasonic ERG2SJ821 5% 2W
69 2R149,R152 68
1206 P68.0FTR-ND Panasonic ERJ-8ENF68R0V 1% 0.25W
70 3SW3,SW4,SW5 PB
PB P13598SCT-ND Panasonic EVQ-PNF05M
71 2TP2,TP3 TESTPOINT
TESTPOINTSMA
LL
5011K-ND KEYSTONE 5011
72 3T4,T5,T6 750110056
XFORM/56
6543
Midcom 750110056
73 1U1 TL431
SO8-NARROW 296-1288-1-ND
Texas Instrume
TL431AIDR
74 1U2 FT232RQ
32QFNW/NO
SPT
806-KUSBVX-
BS1N-W
Kycon KUSBVX-BS1N-W
75 1U3 ADUM3201
SO8-NARROW ADUM3201ARZ-ND
Analog Devices
ADUM3201ARZ
76 1U4 SER EEPROM
SO8-NARROW AT24C1024BW-SH25-B-ND ATMEL AT24C1024BW-SH25-B
77 1U5
71M6543-100TQFP
IC149
100TQFP_SS
Teridian 71M6540F-IGT/F
78 1U6 LNK304-TN
SO8-NARROW 596-1237-1-ND
Power Integrat
LNK304DG-TL
79 1U8 LCD VLS-6648
LCD VLS-6648 VARITRONIX VL_6648_V00
80 1U9
SER EEPROM (uWi re
SO8-NARROW 93LC76C-I/SN-ND MICROCHIP 93LC76CT-I/SN
81 3U15,U16,U17 71M6103-8SOIC
SO8-NARROW Ma xi m 71M6103-IL/F
82 1Y1 32.768KHz
XTAL-ECS-39 Suntsu SPC6-32.768KHZ TR
71M6543 Demo Board User’s Manual
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4.5 71M6543 DEMO BOARD REV 5.0 BILL OF MATERIAL
Table 4-3: 71M6543 REV 5.0 Demo Board: Bill of Material (1/3)
Item QReference Part Footprint Digi-Key P/N Mous er P/N Manufacturer Manufacturer P/N Tol Rating HDR DNP
1 2 BT1 ,BT2 BATTERY
BAT 3 PIN
BARREL
COMBO
DNP
2 1 BT3 BATTERY
BAT CR2032
MAX
DNP
3 1 CN1 USB-B
USBV
806-KUSBVX-BS1
Kycon KUSBVX-BS1N-W
423 C1,C8,C9,C11,C13,C14,C15, 1000pF
603 445-1298-1-ND TDK C1608X7R2A102K 10% 100V
C29,C32,C36,C37,C38,C40,
C41,C42,C44,C49,C50,C52,C53,
C57,C61
5 1 C2 22uF
SM/CT_3216 478-1663-1-ND AVX TAJA226K010RNJ 10% 10V
618 C3,C5,C18,C19,C20,C21, 0.1uF
603 445-1314-1-ND TDK C1608X7R1H104K 0.1 50V
C22,C26,C27,C28,C51,C60,
C62,C63,C64,C66,C74,C77
7 4 C6,C7,C45,C47 10uF
SM/CT_3216 478-1654-1-ND AVX TAJA106K010R 0.1 10V
8 3 C17,C34,C56 1uF
603 445-1604-1-ND TDK C1608X7R1C105K 10% 16V DNP
9 1 C24 15pF
603 445-1271-1-ND TDK C1608C0G1H150J 5% 50V
10 1C25 10pF
603 445-1269-1-ND TDK C1608C0G1H100D 5% 50V
11 2C30,C31 22pF
603 445-1273-1-ND TDK C1608C0G1H220J 5% 50V
12 6C48,C58,C65, 1000pF
603 445-1298-1-ND TDK C1608X7R2A102K 0.1 100V DNP
C67,C68,C69
13 1C35 2.2uF
CYL/D.400/LS.
200/.034
493-1227-ND Nichicon UVR2G2R2MPD 400V
14 1C39 100uF
CYL/D.400/LS.
200/.034
P963-ND Panasonic ECE-A1AKS101 0.2 10V
15 1C46 0.03 uF
HIGH VOLT
DISC CAP
75-125LS30-R Vishay/BC 125LS30-R 1000V
16 1C54 0.1uF
603 445-1314-1-ND TDK C1608X7R1H104K 10% 50V DNP
17 2C55,C59 100pF
603 445-1281-1-ND TDK C1608C0G1H101J 5% 50V
18 2C70,C71 0.1uF
805 478-3351-1-ND
AVX Corporatio
08055C104MAT2A 0.2 50V
19 1C72 0.01uF
603 478-1227-1-ND
AVX Corporatio
06035C103KAT2A 0.1 50V
20 1C73 4.7uF
805 587-1782-1-ND Taiyo Yuden TMK212BJ475KG-T 0.1 25V
21 2D5,D6 LED_1
LED6513 67-1612-ND Lumex SSL-LX5093SRC/E
22 1D7 LD274
LED6513 475-1461-ND Osra m SFH 4511
23 4D8,D12,D13,D14 S1J
SMA/DIODE RS1J-E3/61TGICT-ND
Vishay/Genera
S1J-E3/61T
24 1D9 ES1J
SMA/DIODE ES1JFSCT-ND Vishay ES1J
25 1D10 LED
805 L62415CT-ND CML CMD17-21UGC/TR8
26 1D17 1.5KE350A
DO-41 1.5KE350CALFCT-ND Littelfuse 1.5KE350CA
27 5JP1,J1,JP3,JP44,JP45 HDR3X1
BLKCON.100/V
H/TM1SQ/W.1
00/3
S1011E-36-ND Sullins PBC36SAAN 0.1
28 1JP2 HDR5X1
BLKCON.100/V
H/TM1SQ/W.1
00/5
S1011E-36-ND Sullins PBC36SAAN 0.2
29 25 TP1,J3,JP4,JP5,JP6,JP7, HDR2X1
BLKCON.100/V
H/TM1SQ/W.1
00/2
S1011E-36-ND Sullins PBC36SAAN 0.1
JP8,J11,J12,J13,J15,J16,
J17,J18,J20,J22,J23,J24,
J25,JP50,JP51,JP52,JP53,
JP54,JP55
30 1JP20 SWITCHCRAFT
SWITCHCRAFT SC237-ND
Switchcraft Inc.
RAPC712X
31 4J4,J6,J8,J9 Spade Terminal
FASTON A24747CT-ND Tyco/AMP 62395-1
32 1J14 ICE Header
RIBBON6513O
UTLINE
A33555-ND
571-5-104068-
1
Tyco/AMP 5-104068-1
33 1J19 HDR5X2
BLKCON.100/V
H/TM2OE/W.2
00/10
S2011E-36-ND Sullins PBC36DAAN 0.2
34 1J21 HDR8X2
BLKCON.100/V
H/TM2OE/W.2
00/16
S2011E-36-ND Sullins PBC36DAAN 0.3
35 15 L1,L2,L3,L4,L5,L6,L7,L9,
Ferrite Bead 600oh
805 445-1556-1-ND TDK MMZ2012S601A 0.5A
L10,L11,L12,L13,L16,L17,
L18
36 1L8 180uH
RFB0807 CoilCraft RFB0807-181L
37 1Q1 BP103
LED6513 475-1437-ND Osra m SFH 300-3/4 DNP
38 3RV1,RV2,RV3 VARISTOR
MOV CPS
2381594
594-2381-594-
55116
AVX 2381 594 55116
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Table 4-4: 71M6543 REV 5.0 Demo Board: Bill of Material (2/3)
Item QReference Part Footprint Digi-Key P/N Mous er P/N Manufacturer Manufacturer P/N Tol Rating HDR DNP
39 2R1,R2 1K
805 541-1.0KACT-ND Vishay/Dale CRCW08051K00JNEA 5%
0.125W
40 1R4 100
805 541-100ACT-ND Vishay/Dale CRCW0805100RJNEA 5%
0.125W
41 3R6,R7,R8 75K
AXLE FLAME
UPRIGHT
75KW-2-ND Yageo RSF200JB-75K 5% 2W DNP
42 6R9,R10,R11,R15,R16,R17 62
603 P62GCT-ND Panasonic ERJ-3GEYJ620V 5% 0.1W
43 2R12,R13 100K
603 P100KGCT-ND Panasonic ERJ-3GEYJ104V 0.05 0.1W
44 5R14,R33,R52,R54,R72 750
805 RR12P750DCT-ND Susumu RR1220P-751-D 0.01 0.1W
45 1R18 0
1206 RHM0.0ECT-ND
Rohm Semicond
MCR18EZHJ000 5% 0.25W
46 3R19,R106,R137 1K
603 P1.00KHCT-ND Panasonic ERJ-3EKF1001V 1% 0.1W
47 1R20 8.06K
805 RHM8.06KCCT-ND Rohm MCR10EZHF8061 1%
0.125W
48 1R21 25.5K
805 P25.5KCCT-ND Panasonic ERJ-6ENF2552V 1%
0.125W
49 12 R24,R25,R26,R27,R28,R29, 5.1
MELF
71-
SMM02040C5
108FB30
Vishay/Dale SMM02040C5108FB30 0.01
0.125W
R30,R31,R32,R34,R35,R36
50 3R38,R39,R58 4.7K
805 RG20P4.7KBCT-ND TDK RG2012P-472-B-T5 0%
0.125W
51 6R46,R47,R59,R60,R62,R64 270K
805 RG20P270KBCT-ND Susumu RG2012P-274-B-T5 0%
0.125W
52 3R61,R63,R66 2M
AXLE FLAME
UPRIGHT
71-RN65D-F-
2.0M
Vishay/Dale RN65D2004FB14 0.01 0.5W
53 3R65,R73,R141 100
AXLE FLAME
UPRIGHT
100W-2-ND Ya geo RSF200JB-100R 5% 2W
54 12 R74,R89,R90,R93,R94,R95, 10K
603 P10.0KHCT-ND Panasonic ERJ-3EKF1002V 0.01 0.1W
R96,R103,R107,R109,R142,
R144
55 7R76,R81,R82,R104,R105, 10K
805 541-10KACT-ND Vishay/Dale CRCW080510K0JNEA 5%
0.125W
R108,R151
56 1R77 100K
603 541-10KACT-ND Panasonic ERJ-3GEYJ104V 5% 0.1W DNP
57 2R79,R150 100
603 P100GCT-ND Panasonic ERJ-3GEYJ101V 5% 0.1W
58 3R91,R100,R101 0
RES_TH_50 0 0.0EBK-ND Yageo ZOR-12-B-52 1% 0.1W
59 6R92,R97,R98,R99,R102, 750
RES_TH_50 0 270-750-RC Xicon 270-750-RC 1% 0.1W
R112
60 1R110 2K
603 P2.00KHCT-ND Panasonic ERJ-3EKF2001V 1% 0.1W
61 1R111 4.02K
603 P4.02KHCT-ND Panasonic ERJ-3EKF4021V 1% 0.1W
62 2R138,R143 10K
603 P10.0KHCT-ND Panasonic ERJ-3EKF1002V 1% 0.1W DNP
63 1R139 1.5
1206 541-1.5ECT-ND Vishay/Dale CRCW12061R50JNEA 5% 0.25W
64 3R140,R146,R147 3.4K
805 541-3.40KCCT-ND Vishay/Dale CRCW08053K40FKEA 1%
0.125W
65 1R148 820
AXLE FLAME
UPRIGHT
P820W-2BK-ND Panasonic ERG2SJ821 5% 2W
66 2R149,R152 68
1206 P68.0FTR-ND Panasonic ERJ-8ENF68R0V 1% 0.25W
67 3SW3,SW4,SW5 PB
PB P13598SCT-ND Panasonic EVQ-PNF05M
68 2TP2,TP3 TESTPOINT
TESTPOINTSMA
LL
5011K-ND KEYSTONE 5011
69 3T4,T5,T6 750110056
XFORM/56
6543
Midcom 750110056 DNP
70 1U1 TL431
SO8-NARROW 296-1288-1-ND
Texas Instrume
TL431AIDR
71 1U2 FT232RQ
32QFNW/NO
SPT
768-1008-1-ND FTDI FT232RQ-REEL
72 1U3 ADUM3201
SO8-NARROW ADUM3201ARZ-ND
Analog Devices
ADUM3201ARZ
73 1U4 SER EEPROM
SO8-NARROW AT24C1024BW-SH25-B-ND ATMEL AT24C1024BW-SH25-B
74 1U5
71M6543-100TQFP
IC149
100TQFP_SS
Teridian 71M6540F-IGT/F
75 1U6 LNK304-TN
SO8-NARROW 596-1237-1-ND
Power Integrat
LNK304DG-TL
76 1U8 LCD VLS-6648
LCD VLS-6648 VARITRONIX VL_6648_V00
77 1U9
SER EEPROM (uWi re
SO8-NARROW 93LC76C-I/SN-ND MICROCHIP 93LC76CT-I/SN
78 3U15,U16,U17 71M6103-8SOIC
SO8-NARROW Ma xi m 71M6103-IL/F DNP
79 1Y1 32.768KHz
XTAL-ECS-39 Suntsu SPC6-32.768KHZ TR
71M6543 Demo Board User’s Manual
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4.6 71M6543 REV 4.0 DEMO BOARD PCB LAYOUT
Figure 4-10: Teridian 71M6543 REV 4.0 Demo Board: Top View
71M6543 Demo Board User’s Manual
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Figure 4-11: Teridian 71M6543 REV 4.0 Demo Board: Top Copper
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Figure 4-12: Teridian 71M6543 REV 4.0 Demo Board: Bottom View
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Figure 4-13: Teridian 71M6543 REV 4.0 Demo Board: Bottom Copper
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4.7 71M6543 REV 5.0 DEMO BOARD PCB LAYOUT
Figure 4-14: Teridian 71M6543 REV 5.0 Demo Board: Top View
71M6543 Demo Board User’s Manual
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Figure 4-15: Teridian 71M6543 REV 5.0 Demo Board: Top Copper
71M6543 Demo Board User’s Manual
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Figure 4-16: Teridian 71M6543 REV 5.0 Demo Board: Bottom View
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Figure 4-17: Teridian 71M6543 REV 5.0 Demo Board: Bottom Copper
71M6543 Demo Board User’s Manual
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4.8 DEBUG BOARD BILL OF MATERIAL
Table 4-5: Debug Board: Bill of Material
Item QReference Value PCB Footprint P/N Manufacturer Vendor Vendor P/N
121 C1-C3,C5-C10,C12-C23 0.1uF 0805 C2012X7R1H104K TDK Digi-Key 445-1349-1-ND
2 1 C4 33uF/10V 1812 TAJB336K010R AVX Digi-Key 478-1687-1-ND
3 1 C11 10uF/16V, B Case 1812 TAJB106K016R AVX Digi-Key 478-1673-1-ND
4 2 D2,D3 LED 0805 LTST-C170KGKT LITEON Digi-Key 160-1414-1-ND
5 4 JP1,JP2,JP3,JP4 HDR2X1 2x1pin PZC36SAAN Sullins Digi-Key S1011-36-ND
6 1 J1 RAPC712 RAPC712 Switchcraft Digi-Key SC1152-ND
7 1 J2 DB9 DB9 A2100-ND AMP Digi-Key A2100-ND
8 1 J3 HEADER 8X2 8x2pin PPTC082LFBN Sullins Digi-Key S4208-ND
9 4 R1,R5,R7,R8 10K 0805 ERJ-6GEYJ103V Panasonic Digi-Key P10KACT-ND
10 2R2,R3 1K 0805 ERJ-6GEYJ102V Panasonic Digi-Key P1.0KACT-ND
11 1R4 NC 0805 N/A N/A N/A N/A
12 1R6 00805 ERJ-6GEY0R00V Panasonic Digi-Key P0.0ACT-ND
13 1SW2 PB Switch PB EVQ-PJX05M Panasonic Digi-Key P8051SCT-ND
14 2TP5,TP6 test point TP 5011 Keystone Digi-Key 5011K-ND
15 5U1,U2,U3,U5,U6 ADUM1100 SOIC8 ADUM1100AR ADI Digi-Key ADUM1100AR-ND
16 1U4 MAX3237CAI SOG28 MAX3237CAI MAXIM Digi-Key MAX3237CAI-ND
17 4spacer 2202K-ND Keystone Digi-Key 2202K-ND
18 44-40, 1/4" screw PMS4400-0025PH Building Fasteners Digi-Key H342-ND
19 24-40, 5/16" screw PMS4400-0031PH Building Fasteners Digi-Key H343-ND
20 24-40 nut HNZ440 Building Fasteners Digi-Key H216-ND
71M6543 Demo Board User’s Manual
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4.9 DEBUG BOARD SCHEMATICS
Figure 4-18: Debug Board: Electrical Schematic
+
C11
10uF, 16V (B Case)
C15
0.1uF
C13
0.1uF
VDD1 1
DIN 2
VDD1 3
GND1 4
GND2
5DOUT
6GND2
7VDD2
8
U5
ADUM1100
VDD1
1
DIN
2
VDD1
3
GND1
4GND2 5
DOUT 6
GND2 7
VDD2 8
U6
ADUM1100
C19
0.1uF
GND_DBG
C23
0.1uF
GND_DBG
GND
C21
0.1uF
V5_DBG
GND
V3P3
C14
0.1uF
C18
0.1uF
C17
0.1uF
C2
0.1uF
GND_DBG
C1
0.1uF
V3P3
GND
DIO02
V5_DBG
GND_DBG
C3
0.1uF
V5_DBG
GND_DBG
DIO01
VDD1 1
DIN 2
VDD1 3
GND1 4
GND2
5DOUT
6GND2
7VDD2
8
U2
ADUM1100
DIO00
GND_DBG GND
C8
0.1uF
GND_DBG
GND_DBG
V5_DBG DIO01_DBG
C5
0.1uF
V3P3
C6
0.1uF
R2
1K
D2
LED
GND_DBG
DIO01
V5_DBG
GND
GND
232VP1
R XPC
232VN1
232C1P1
232C1M1
232C2M1
R1
10K
GND_DBG
GND
R3
1K
C10
0.1uF
V5_DBG
GND_DBG
GND
DIO00
VDD1 1
DIN 2
VDD1 3
GND1 4
GND2
5DOUT
6GND2
7VDD2
8
U3
ADUM1100
V3P3
C9
0.1uF
V3P3
C12
0.1uF
GND
GND_DBG
V5_DBG
D3
LED
DIO00_DBG
GND_DBG
V5_DBG
C22
0.1uF
1
2
JP4
HDR2X1
GND_DBG
VDD1
1
DIN
2
VDD1
3
GND1
4GND2 5
DOUT 6
GND2 7
VDD2 8
U1
ADUM1100
V5_DBG
GND_DBG
GND_DBG
GND_DBG
GND
GND
GND
UAR T_TX
V3P3
V3P3
GND
UART_RX_T
SW2
DISPLAY SEL
C20
0.1uF
GND
V5_DBG
GND_DBG
1
2
3
J1
RAPC712
C16
0.1uF
V3P3
GND
V5_DBG
V5_DBG
GND_DBG
GND
GND
TP6
TP
TP5
TP
R7
10K
R5
10K
R4
NC
1
6
2
7
3
8
4
9
5
J2
DB9_RS232
R8
10K
5Vdc EXT SUPPLY
DEBUG CONNECTOR
STATUS LEDs
RS232 TRANSCEIVER
R6
0
UART_RX
TX232
NORM A L
12
34
56
78
910
11 12
13 14
15 16
J3
HEADER 8X2
DIO00
GND
GND
GND
DIO02
V5_DBG
GND_DBG
GND
CKTEST
V3P3
DIO01
UART_RX_T
UAR T_TX
TMUXOU T
V5_DBG
GND_DBG
232C2P1
NORM A L
NULL
NULL
RX232
V5_DBG
GND_DBG
GND_DBG
TXPC
TXI SO
RXISO
+C4
33uF, 10V C7
0.1uF
1
2
JP3
HDR2X1
1
2
JP1
HDR2X1
1
2
JP2
HDR2X1
C1+ 28
C1- 25
C2+ 1
C2- 3
T1I N 24
T2I N 23
T3I N 22
T4I N 19
T5I N 17
R1OUTBF 16
R1OUT 21
R2OUT 20
R3OUT 18
GND
2
MBAUD
15
SHDNB
14 ENB
13
R3IN
11 R2IN
9R1IN
8
T1OU T
5
T2OU T
6
T3OU T
7
T4OU T
10
T5OU T
12
V-
4
V+
27
VCC 26
U4
MAX3237CAI
71M6543 Demo Board User’s Manual
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4.10 OPTIONAL DEBUG BOARD PCB LAYOUT
Figure 4-19: Debug Board: Top View
Figure 4-20: Debug Board: Bottom View
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Figure 4-21: Debug Board: Top Signal Layer
Figure 4-22: Debug Board: Middle Layer 1 (Ground Plane)
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Figure 4-23: Debug Board: Middle Layer 2 (Supply Plane)
Figure 4-24: Debug Board: Bottom Trace Layer
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4.11 71M6543 PIN-OUT INFORMATION
Power/Ground/NC Pins:
Table 4-6: 71M6543 Pin Description Table 1/3
Name
Type
Description
GNDA
P
Analog ground: This pin should be connected directly to the ground plane.
GNDD
P
Digital ground: This pin should be connected directly to the ground plane.
V3P3A P
Analog power supply: A 3.3 V power supply should be connected to this pin.
V3P3A must be the same voltage as V3P3SYS.
V3P3SYS P
System 3.3 V supply. This pin should be connected to a 3.3 V power supply.
V3P3D O
Auxiliary voltage output of the chip. In mission mode, this pin is connected
to V3P3SYS by the internal selection switch. In BRN mode, it is internally
connected to VBAT. V3P3D is floating in LCD and sleep mode. A bypass
capacitor to ground should not exceed 0.1 µF.
VDD O
The output of the 2.5V regulator. This pin is powered in MSN and BRN
modes. A 0.1 µF bypass capacitor to ground should be connected to this
pin.
VLCD O
The output of the LCD DAC. A 0.1 µF bypass capacitor to ground should be
connected to this pin.
VBAT P
Battery backup pin to support the battery modes (BRN, LCD). A battery or
super-capacitor is to be connected between VBAT and GNDD. If no battery
is used, connect VBAT to V3P3SYS.
VBAT_RTC P
RTC and oscillator power supply. A battery or super-capacitor is to be con-
nected between VBAT and GNDD. If no battery is used, connect
VBAT_RTC to V3P3SYS.
Analog Pins:
Table 4-7: 71M6543 Pin Description Table 2/3
Name
Type
Description
IAP/IAN,
IBP/IBN,
ICP/ICN
IDP/IDN
I
Differential or single-ended Line Current Sense Inputs: These pins are voltage
inputs to the internal A/D converter. Typically, they are connected to the outputs
of current sensors. Unused pins must be tied to V3P3A.
Pins IBP/IBN, ICP/ICN, and IDP/IDN may be configured for communication with
the remote sensor interface (71M6x0x).
VA, VB,
VC I
Line Voltage Sense Inputs: These pins are voltage inputs to the internal A/D
converter. Typically, they are connected to the outputs of resistor dividers. Un-
used pins must be tied to V3P3A.
VREF
O
Voltage Reference for the ADC. This pin should be left unconnected (floating).
XIN
XOUT
I
O
Crystal Inputs: A 32 kHz crystal should be connected across these pins. Typical-
ly, a 15 pF capacitor is also connected from XIN to GNDA and a
10 pF capacitor is connected from XOUT to GNDA. It is important to minimize
the capacitance between these pins. See the crystal manufacturer datasheet for
details.
If an external clock is used, a 150 mV (p-p) clock signal should be applied to
XIN, and XOUT should be left unconnected.
Pin types: P = Power, O = Output, I = Input, I/O = Input/Output
71M6543 Demo Board User’s Manual
Page: 89 of 91 v5
Digital Pins:
Table 4-8: 71M6543 Pin Description Table 3/3
Name
Type
Description
COM3,COM2,
COM1,COM0
O
LCD Common Outputs: These 4 pins provide the select signals for
the LCD display.
SEGDIO0 …
SEGDIO45 I/O
Multi-use pins, configurable as either LCD segment driver or DIO.
Alternative functions with proper selection of associated I/O RAM
registers are:
SEGDIO0 = WPULSE
SEGDIO1 = VPULSE
SEGDIO2 = SDCK
SEGDIO3 = SDATA
SEGDIO6 = XPULSE
SEGDIO7 = YPULSE
Unused pins must be configured as outputs or terminated to
V3P3/GNDD.
SEGDIO26/ COM5,
SEGDIO27/ COM4
I/O
Multi-use pins, configurable as either LCD segment driver or DIO with
alternative function (LCD common drivers).
SEGDIO36/
SPI_CSZ,
SEGDIO37/ SPI_DO,
SEGDIO38/ SPI_DI,
SEGDIO39/ SPI_CKI
I/O Multi-use pins, configurable as either LCD segment driver or DIO with
alternative function (SPI interface).
SEGDIO51/
OPT_TX,
SEGDIO55/ OPT_RX
I/O Multi-use pins, configurable as either LCD segment driver or DIO with
alternative function (optical port/UART1)
E_RXTX/SEG48
I/O Multi-use pins, configurable as either emulator port pins (when ICE_E
pulled high) or LCD segment drivers (when ICE_E tied to GND).
E_RST/SEG50
E_TCLK/SEG49
O
ICE_E I
ICE enable. When zero, E_RST, E_TCLK, and E_RXTX become
SEG50, SEG49, and SEG48 respectively. For production units, this
pin should be pulled to GND to disable the emulator port.
TMUXOUT/ SEG47,
TMUX2OUT/ SEG46
O
Multi-use pins, configurable as either multiplexer/clock output or LCD
segment driver using the I/O RAM registers.
RESET I
Chip reset: This input pin is used to reset the chip into a known state.
For normal operation, this pin is pulled low. To reset the chip, this pin
should be pulled high. This pin has an internal 30 μA (nominal) cur-
rent source pull-down. No external reset circuitry is necessary.
RX I
UART0 input. If this pin is unused it must be terminated to
V3P3D or GNDD.
TX
O
UART0 output.
TEST I
Enables Production Test.
This pin must be grounded in normal operation.
PB I
Push button input. This pin must be at GNDD when not active or un-
used. A rising edge sets the IE_PB flag. It also causes the part to wake
up if it is in SLP or LCD mode. PB does not have an internal pull-up or
pull-down resistor.
NC
N/C
Do not connect this pin.
Pin types: P = Power, O = Output, I = Input, I/O = Input/Output,
71M6543 Demo Board User’s Manual
Page: 90 of 91 v5
Figure 4-25: 71M6543, LQFP100: Pin-out (top view)
1
Teridian
71M6543F
71M6543H
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
91
92
93
94
95
96
97
98
99
10026
27
28
29
30
51
52
53
54
55
56
57
58
59
60
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
SEGDIO17
TMUXOUT/SEG47
SPI_DI/SEGDIO38
TX
V3P3D
SEGDIO1/VPULSE
SEGDIO3/SDATA
SPI_CSZ/SEGDIO36
V3P3SYS
COM1
COM2
COM3
COM0
SEGDIO45
NC
XIN
GNDD
VBAT
ICE_E
SEGDIO52
OPT_TX/SEGDIO51
VB
VC
V3P3A
GNDA
VA
PB
VLCD
TEST
OPT_RX/SEGDIO55
ICN
XOUT
IAP
IBN
ICP
IAN
IBP
IDP
SEGDIO27/COM4
IDN
SPI_DO/SEGDIO37
SEGDIO26/COM5
SEGDIO25
SEGDIO24
SEGDIO23
SEGDIO22
SEGDIO21
SEGDIO20
SEGDIO19
SEGDIO35
SEGDIO33
SEGDIO32
SEGDIO30
SEGDIO29
SEGDIO31
SEGDIO28
SEGDIO34
SEGDIO18
GNDA
VBAT_RTC
E_RXTX/SEG48
E_TCLK/SEG49
E_RST/SEG50
RX
SEGDIO53
RESET
TMUX2OUT/SEG46
SEGDIO44
SEGDIO43
SEGDIO42
SEGDIO41
SEGDIO40
SPI_CKI/SEGDIO39
SEGDIO16
SEGDIO15
SEGDIO14
SEGDIO13
SEGDIO10
SEGDIO11
SEGDIO12
SEGDIO9
SEGDIO8/DI
SEGDIO7/YPULSE
SEGDIO6/XPULSE
SEGDIO5
SEGDIO4
SEGDIO2/SDCK
SEGDIO0/WPULSE
SEGDIO54
VREF
NC
NC
NC
NC
VDD
NC
NC
NC
NC
NC
71M6543 Demo Board User’s Manual
Page: 91 of 91 v5
4.12 REVISION HISTORY
Revision
Date
Description
2.0 02-19-2010 Initial release based on DBUM revision 1.0 for 6543 REV 1.0 Demo Board.
2.1 02-23-2010 Minor corrections. Added more figures illustrating shunt arrangements.
2.2 03-01-2010
Specified type of Remote Sensor used on REV 2.0 board (71M6113 or
71M6203). Improved Table 1-9. Added description for i_max2 variable
used to control neutral current. Improved page layout.
2.3 03-04-2010 Changed type of Remote Sensor Interface from 71M6113 to 71M6103.
Updated schematics and BOM of the REV 2.0 Demo Board.
2.4 06-16-2010
Corrected “X” factor for
WRATE
calculation to 0.09375. Changed section
on shunt arrangement. Improved description on temperature compensa-
tion. Added Figure 1.7 and section 1.10.7.
2.5 06-21-2010 Added part numbers for shunt resistors.
3.0 07-26-2010
Added documentation for 6543 REV 3.0 Demo Board. Updated calibration
spread sheets.
3.1 08-10-2010
Fixed display of calibration spread sheets in PDF file. Replaced Teridian
Logo with Maxim Logo.
3.2 12-10-2010
Updated information on temperature compensation and on Demo Board
revision 3.0.
4.0 02-16-2011
Updated to match board revisions 4.0 and 5.0. Removed information on
older board revisions (3.0).
Added comments on schematics.
4.1 03-28-2011
Updated schematics and BOM for DB6543 REV5.0. Added explanation
and table of Demo Code versions.
4.2 05-06-2011
Added explanation on technique to avoid cross-talk between shunt resis-
tors.
5 7/2012
Corrected addresses for auto-calibration parameter in CLI table.
Corrected entries in table 1-11 (meter accuracy classes). Changed color
for all table headings from yellow to gray.
Corrected formula in 2.3.3.1. Removed text stating that the Demo Code
and documents/tools are delivered on a CD-ROM in the kit. Added attribute
‘optional’ for all references to the ‘Debug Board’. Added USB Interface
Module as part of Demo Kit Contents.
Added text stating that spreadsheets are available on the Maxim web site.
Updated graphs and text in Serial Connection Setup (1.7.4) and updated
Demo Code version in Compatibility (1.5).
Updated images for calibration spreadsheets and changed description of
calibration to reflect the usage of LCOMP2_n coefficients used in newer
codes.
Added section 1.10.8 (Bootloader Feature).
