TERIDIAN 71M6511H-IGT

71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
GENERAL DESCRIPTION
FEATURES
The TERIDIAN 71M6511 is a highly integrated SOC with an MPU core,
RTC, FLASH and LCD driver. TERIDIAN’s patented Single Converter
Technology with a 22-bit delta-sigma ADC, 3 analog inputs, digital
temperature compensation, precision voltage reference and 32-bit
computation engine (CE) supports a wide range of single-phase metering
applications with very few low cost external components. A 32kHz crystal
time base for the entire system and internal battery backup support for RAM
and RTC further reduce system cost.
Maximum design flexibility is supported with multiple UARTs, I2C, a power
fail comparator, a 5V LCD charge pump, up to 12 DIO pins and an insystem programmable FLASH. The device is offered in high (0.1%) and
standard (0.5%) accuracy versions for multifunction residential/commercial
meter applications requiring multiple voltage/current inputs and complex
LCD or DIO configurations.
A complete array of ICE and development tools, programming libraries and
reference designs enable rapid development and certification of meters that
meet most demanding worldwide electricity metering standards.
LIVE
Wh accuracy over temperature and
2000:1 range
< 0.1% -- 71M6511H,
<0.5% -- 71M6511
Exceeds IEC62053 / ANSIC12.20.
Voltage reference
< 10ppm/°C -- 71M6511H,
< 50ppm/°C -- 71M6511
Three sensor inputs - VDD
referenced
Low jitter Wh/VARh pulse outputs
Pulse count for pulse outputs
Four-quadrant metering
Voltage/current angle
Line frequency count for RTC
Digital temperature compensation
CT/SHUNT
POWER SUPPLY
Sag detection
LOAD
NEUT
Independent 32-bit compute engine
CONVERTER
IA
Phase compensation (±7°)
5V BOOST
VA
V or I
40-70Hz line frequency range with
same calibration
V3.3A V3.3D GNDA GNDD
TERIDIAN
71M6511
IB
VDRV
Battery Backup for RAM and RTC
REGULATOR
VBAT
BATTERY
V2.5
VOLTAGE REF
TEMP
SENSOR
VREF
RAM
VBIAS
SERIAL PORTS
AMR
IR
TX
32 kHz
COM0..3
3V/5V LCD
FLASH
SEG0..19
SEG 24..32
DIO 0..11
88.88.8888
COMPUTE
ENGINE
SEG 32..41
DIO 12..21
EEPROM
RX
SENSE
DRIVE
RX
TX
COMPARATOR
POWER
FAULT
Flash memory option with security
LCD DRIVER
DIO, PULSE
VLCD
V1
OSC/PLL
XIN
XOUT
MPU
22mW @3.3V, 7.2µW back up
TEST PULSES
22-bit delta-sigma ADC
8-bit MPU (80515) - 1 clock cycle per
instruction
LCD driver (≤128 pixels)
High speed SSI serial output
RTC for time-of-use functions
RTC
TIMERS
Hardware watchdog timer
ICE
7/20/2007
Up to 12 general purpose I/O pins
64KB Flash, 7KB RAM
Two UARTs for IR and AMR
64-lead LQFP package
Page: 1 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Table of Contents
GENERAL DESCRIPTION .......................................................................................................................................... 1
FEATURES.................................................................................................................................................... 1
HARDWARE DESCRIPTION....................................................................................................................................... 8
Hardware Overview........................................................................................................................................ 8
Analog Front End (AFE)................................................................................................................................. 8
Multiplexer ....................................................................................................................................... 8
ADC................................................................................................................................................. 9
FIR Filter.......................................................................................................................................... 9
Voltage Reference........................................................................................................................... 9
Temperature Sensor........................................................................................................................ 10
Functional Description ..................................................................................................................... 10
Computation Engine (CE) .............................................................................................................................. 11
Meter Equations .............................................................................................................................. 12
Pulse Generator .............................................................................................................................. 12
Real-Time Monitor ........................................................................................................................... 13
CE Functional Overview .................................................................................................................. 13
80515 MPU Core ........................................................................................................................................... 15
80515 Overview............................................................................................................................... 15
Memory Organization ...................................................................................................................... 15
Special Function Registers (SFRs).................................................................................................. 17
Special Function Registers (Generic 80515 SFRs) ......................................................................... 18
Special Function Registers Specific to the 71M6511....................................................................... 20
Instruction Set.................................................................................................................................. 21
UART............................................................................................................................................... 21
Timers and Counters ....................................................................................................................... 24
WD Timer (Software Watchdog Timer)............................................................................................ 26
Interrupts ......................................................................................................................................... 29
External Interrupts ........................................................................................................................... 31
Interrupt Priority Level Structure ...................................................................................................... 33
Interrupt Sources and Vectors ......................................................................................................... 34
On-Chip Resources ....................................................................................................................................... 36
DIO Ports......................................................................................................................................... 36
Physical Memory ............................................................................................................................. 37
Oscillator.......................................................................................................................................... 38
Real-Time Clock (RTC) ................................................................................................................... 39
LCD Drivers ..................................................................................................................................... 39
LCD Voltage Boost Circuitry ............................................................................................................ 40
UART (UART0) and Optical Port (UART1) ...................................................................................... 40
Hardware Reset Mechanisms.......................................................................................................... 41
Reset Pin (RESETZ) ....................................................................................................................... 41
Hardware Watchdog Timer.............................................................................................................. 41
Crystal Frequency Monitor............................................................................................................... 41
V1 Pin.............................................................................................................................................. 41
I2C Interface (EEPROM) ................................................................................................................. 42
Internal Clocks and Clock Dividers .................................................................................................. 43
Page: 2 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Battery ............................................................................................................................................. 43
Internal Voltages (VBIAS, VBAT, V2P5).......................................................................................... 43
Test Ports ........................................................................................................................................ 44
FUNCTIONAL DESCRIPTION..................................................................................................................................... 46
Theory of Operation ....................................................................................................................................... 46
System Timing Summary............................................................................................................................... 47
Data Flow....................................................................................................................................................... 49
CE/MPU Communication ............................................................................................................................... 49
Fault, Reset, Power-Up.................................................................................................................................. 50
Battery Operation........................................................................................................................................... 51
Power Save Modes........................................................................................................................................ 51
Temperature Compensation .......................................................................................................................... 52
Chopping Circuitry ......................................................................................................................................... 52
Internal/External Pulse Generation and Pulse Counting ................................................................................ 54
Program Security ........................................................................................................................................... 55
FIRMWARE INTERFACE ............................................................................................................................................ 56
I/O RAM MAP – In Numerical Order .............................................................................................................. 56
SFR MAP (SFRs Specific to TERIDIAN 80515) – In Numerical Order .......................................................... 57
I/O RAM (Configuration RAM) – Alphabetical Order ...................................................................................... 58
CE Program and Environment ....................................................................................................................... 64
CE Program..................................................................................................................................... 64
Formats ........................................................................................................................................... 64
Constants ........................................................................................................................................ 64
Environment .................................................................................................................................... 65
CE Calculations ............................................................................................................................... 65
CE RAM Locations......................................................................................................................................... 66
CE Front End Data (Raw Data) ....................................................................................................... 66
CE Status Word............................................................................................................................... 66
CE Transfer Variables ..................................................................................................................... 67
TYPICAL PERFORMANCE DATA............................................................................................................................... 74
Wh Accuracy at Room Temperature.............................................................................................................. 74
VARh Accuracy at Room Temperature.......................................................................................................... 74
Harmonic Performance .................................................................................................................................. 75
Meter Accuracy over Temperature (71M6511H)............................................................................................ 75
APPLICATION INFORMATION ................................................................................................................................... 76
Connection of Sensors (CT, Resistive Shunt, Rogowski Coil) ....................................................................... 76
Distinction between 71M6511 and 71M6511H Parts ..................................................................................... 76
Temperature Compensation and Mains Frequency Stabilization for the RTC ............................................... 77
External Temperature Compensation ............................................................................................................ 78
Temperature Measurement ........................................................................................................................... 78
Connecting LCDs........................................................................................................................................... 79
Connecting I2C EEPROMs............................................................................................................................ 80
Connecting 5V Devices.................................................................................................................................. 80
Optical Interface............................................................................................................................................. 81
Connecting V1 and Reset Pins ...................................................................................................................... 81
Flash Programming........................................................................................................................................ 82
MPU Firmware Library ................................................................................................................................... 82
Page: 3 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
SPECIFICATIONS ....................................................................................................................................................... 83
Electrical Specifications ................................................................................................................................. 83
LOGIC LEVELS............................................................................................................................... 84
VREF, VBIAS .................................................................................................................................. 86
CRYSTAL OSCILLATOR ................................................................................................................ 86
LCD BOOST.................................................................................................................................... 88
LCD DRIVERS ................................................................................................................................ 88
RTC ................................................................................................................................................. 88
RESETZ .......................................................................................................................................... 88
COMPARATORS ............................................................................................................................ 88
RAM AND FLASH MEMORY .......................................................................................................... 89
FLASH MEMORY TIMING .............................................................................................................. 89
EEPROM INTERFACE.................................................................................................................... 89
Recommended External Components ........................................................................................................... 89
Packaging Information ................................................................................................................................... 90
Pinout (Top View) ............................................................................................................................ 91
Pin Descriptions............................................................................................................................... 92
I/O Equivalent Circuits: .................................................................................................................... 94
ORDERING INFORMATION ......................................................................................................................... 95
Figures
Figure 1: IC Functional Block Diagram ............................................................................................................7
Figure 2: General Topology of a Chopped Amplifier ......................................................................................10
Figure 3: AFE Block Diagram ........................................................................................................................11
Figure 4: Samples in Multiplexer Cycle ..........................................................................................................13
Figure 5: Accumulation Interval......................................................................................................................13
Figure 6: Memory Map...................................................................................................................................15
Figure 7: Interrupt Structure...........................................................................................................................35
Figure 8: DIO Ports Block Diagram................................................................................................................36
Figure 9: Oscillator Circuit..............................................................................................................................39
Figure 10: LCD Voltage Boost Circuitry .........................................................................................................40
Figure 11: Voltage Range for V1....................................................................................................................42
Figure 12: Voltage. Current, Momentary and Accumulated Energy ...............................................................46
Figure 13: Timing Relationship between ADC MUX, CE, and Serial Transfers .............................................47
Figure 14: RTM Output Format......................................................................................................................48
Figure 15: SSI Timing, (SSI_FPOL = SSI_RDYPOL = 0) ..............................................................................48
Figure 16: SSI Timing, 16-bit Field Example (External Device Delays SRDY)...............................................48
Figure 17: MPU/CE Data Flow.......................................................................................................................49
Figure 18: MPU/CE Communication (Functional) ..........................................................................................50
Figure 19: MPU/CE Communication (Processing Sequence) ........................................................................50
Figure 20: Timing Diagram for Voltages, Current and Operation Modes after Power-Up ..............................51
Figure 21: Chop Polarity w/ Automatic Chopping...........................................................................................53
Figure 22: Sequence with Alternate Multiplexer Cycles .................................................................................53
Figure 23: Sequence with Alternate Multiplexer Cycles and Controlled Chopping.........................................54
Figure 24: Wh Accuracy, 0.3A - 200A/240V ..................................................................................................74
Figure 25: VARh Accuracy for 0.3A to 200A/240V Performance ...................................................................74
Figure 26: 71M6511H Wh Accuracy over Current at Various Temperatures .................................................74
Page: 4 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Figure 27: Meter Accuracy over Harmonics at 240V, 30A .............................................................................75
Figure 28: Typical Meter Accuracy over Temperature Relative to 25°C (w/ Temperature
Compensation) .....................................................................................................................75
Figure 29: Resistive Voltage Divider (left), Current Transformer (right) .........................................................76
Figure 30: Resistive Shunt (left), Rogowski Coil (right) ..................................................................................76
Figure 31: Crystal Frequency over Temperature ...........................................................................................77
Figure 32: Crystal Compensation...................................................................................................................78
Figure 33: Connecting LCDs..........................................................................................................................79
Figure 34: LCD Boost Circuit .........................................................................................................................79
Figure 35: EEPROM Connection ...................................................................................................................80
Figure 36: Interfacing RX to a 0-5V Signal.....................................................................................................80
Figure 37: Connection for Optical Components .............................................................................................81
Figure 38: Voltage Divider for V1 ...................................................................................................................81
Figure 39: External Components for RESETZ ...............................................................................................82
Tables
Table 1: Inputs Selected in Regular and Alternate Multiplexer Cycles .............................................................8
Table 2: Channel control based on MUX_DIV and FIR_LEN...........................................................................9
Table 3: CE DRAM Locations for ADC Results .............................................................................................12
Table 4: Standard Meter Equations (inputs shown gray are scanned but not used for calculation) ...............12
Table 5: Stretch Memory Cycle Width............................................................................................................16
Table 6: Internal Data Memory Map...............................................................................................................17
Table 7: Special Function Registers Locations ..............................................................................................17
Table 8: Special Function Registers Reset Values ........................................................................................18
Table 9: PSW Register Flags.........................................................................................................................19
Table 10: PSW bit functions...........................................................................................................................19
Table 11: Port Registers ................................................................................................................................20
Table 12: Special Function Registers ............................................................................................................21
Table 13: Baud Rate Generation ...................................................................................................................22
Table 14: UART Modes .................................................................................................................................22
Table 15: The S0CON Register .....................................................................................................................22
Table 16: The S1CON register ......................................................................................................................23
Table 17: The S0CON Bit Functions..............................................................................................................23
Table 18: The S1CON Bit Functions..............................................................................................................24
Table 19: The TMOD Register.......................................................................................................................24
Table 20: TMOD Register Bit Description ......................................................................................................25
Table 21: Timers/Counters Mode Description................................................................................................25
Table 22: The TCON Register .......................................................................................................................25
Table 23: The TCON Register Bit Functions..................................................................................................26
Table 24: Timer Modes ..................................................................................................................................26
Table 25: The PCON Register .......................................................................................................................26
Table 26: The IEN0 Register (see also Table 34) ..........................................................................................27
Table 27: The IEN0 Bit Functions (see also Table 34)...................................................................................27
Table 28: The IEN1 Register (see also Tables 35/36) ...................................................................................27
Table 29: The IEN1 Bit Functions (see also Tables 35/36)............................................................................27
Table 30: The IP0 Register (see also Table 46) ............................................................................................28
Table 31: The IP0 bit Functions (see also Table 46)......................................................................................28
Table 32: The WDTREL Register ..................................................................................................................28
Page: 5 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Table 33: The WDTREL Bit Functions ...........................................................................................................28
Table 34: The IEN0 Register .........................................................................................................................29
Table 35: The IEN0 Bit Functions ..................................................................................................................29
Table 36: The IEN1 Register .........................................................................................................................30
Table 37: The IEN1 Bit Functions ..................................................................................................................30
Table 38: The IEN2 Register .........................................................................................................................30
Table 39: The IEN2 Bit Functions ..................................................................................................................30
Table 40: The TCON Register .......................................................................................................................31
Table 41: The TCON Bit Functions................................................................................................................31
Table 42: The IRCON Register......................................................................................................................31
Table 43: The IRCON Bit Functions ..............................................................................................................31
Table 44: External MPU Interrupts.................................................................................................................32
Table 45: Control Bits for External Interrupts .................................................................................................32
Table 46: Priority Level Groups......................................................................................................................33
Table 47: The IP0 Register: ...........................................................................................................................33
Table 48: The IP1 Register: ...........................................................................................................................33
Table 49: Priority Levels ................................................................................................................................33
Table 50: Interrupt Polling Sequence.............................................................................................................34
Table 51: Interrupt Vectors ............................................................................................................................34
Table 52: Data/Direction Registers and Internal Resources for DIO Pin Groups ...........................................36
Table 53: DIO_DIR Control Bit.......................................................................................................................37
Table 54: Selectable Controls using the DIO_DIR Bits ..................................................................................37
Table 55: MPU Data Memory Map.................................................................................................................37
Table 56: Liquid Crystal Display Segment Table (Typical).............................................................................40
Table 57: EECTRL Status Bits.......................................................................................................................43
Table 58: TMUX[3:0] Selections ....................................................................................................................44
Table 59: SSI Pin Assignment .......................................................................................................................45
Table 60: Power Saving Measures ................................................................................................................51
Table 61: CHOP_EN Bits...............................................................................................................................52
Table 62: Frequency over Temperature.........................................................................................................77
Page: 6 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
VREF
IA
VA
IB
VBIAS
V3P3A
GNDA
GNDA
∆Σ ADC
CONVERTER
VBIAS
VOLTAGE
BOOST
MUX
VDRV
-
V3P3A
FIR
FILTER
+
LCD_IBST
LCD_BSTEN
VREF
MUX
CTRL
VOLT
REG
V3P3D
VBAT
0.1V
MCK
PLL
RTCLK (32KHz)
OSC
(32KHz)
XOUT
GNDD
FIR_LEN
CK32
EQU
MUX_ALT
MUX_DIV
XIN
VREF
CHOP_EN
VREF_DIS
MUX
TEMP
GNDD
OSC_DIS
V2P5
CK_EN
CKTEST
CKFIR
4.9MHz
4.9MHz
CKOUT_EN
CK_GEN
CE RAM
(1KB)
CK_2X
ECK_DIS
MPU_DIV
2.5V to logic
V2P5
VLCD
SSI
CKMPU_2X
MUX_SYNC
WPULSE
VARPULSE
STRT
CKCE
CE
<4.9MHz
LCD DISPLAY
DRIVER
DATA
00-FF
32-bit Compute
Engine
TEST
MUX
RTM
COM0..3
MEMORY SHARE
SEG0..SEG2
PROG
000-7FF
CE
CONTROL
EQU
PRE_SAMPS
SUM_CYCLES
1000-13FF
WPULSE
VARPULSE
CE_RUN
CE PROG
RAM
(4KB)
3000-3FFF
CE_LOAD
I/O RAM
CE_BUSY
XFER BUSY
RTM_EN
CE_EN
CKMPU
<4.9MHz
SCL
EEPROM
INTERFACE
SDA
TX
RX
UART
PROG
0000-FFFF
OPT_TX
OPTICAL
OPT_RX
V1
OPT_TXDIS
VBIAS
POWER FAULT
COMP_STAT
COMP_INT
0000-FFFF
FLASH
(64KB)
EERDSLOW
EEWRSLOW
WAKE
V3P3
EMULATOR
PORT
FAULTZ
DMUX
F
CE_BUSY
RTCLK
E
D
reserved
C
CK_MPU
B
CK_10M
MUX_SYNC
A
9
OPTRX
8
reserved
7
reserved
WDTR_EN
6
5
RTM
4
VBIAS
3
PLL_2.5V
IBIAS
2
1
DGND
RESETZ
SEG3/SCLK
SEG4/SSDATA
SEG5/SFR
SEG6/SRDY
SEG7/
MUX_SYNC
CONFIGURATION
PARAMETERS
XFER_BUSY
MPU XRAM
(2KB)
RTCLK
RTC
2000-20FF
0000-07FF
SEG24/DIO4 ...
SEG31/DIO11
SEG34/DIO14 ...
SEG37/DIO17
RTC_HOLD
RTC_SET
CONFIG
RAM
DATA
0000-FFFF
MPU
(8051)
SEG8..SEG19
LCD_NUM
LCD_MODE
LCD_CLK
LCD_EN
DIGITAL I/O
DIO_EEX
PULSEV/W
DIO_IN
DIO_OUT
LCD_NUM
DIO_GP
DIGITAL
ANALOG
TMUXOUT
0
TMUX
October 5, 2005
Figure 1: IC Functional Block Diagram
Page: 7 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
HARDWARE DESCRIPTION
Hardware Overview
The TERIDIAN 71M6511 single chip single-phase meter integrates all primary functional blocks required to implement a solidstate electricity meter. Included on chip are an analog front end (AFE), an 8051-compatible microprocessor (MPU) which
executes one instruction per clock cycle (80515), an independent 32-bit digital computation engine (CE), a voltage reference, a
temperature sensor, LCD drivers, RAM, FLASH memory, a real time clock (RTC), and a variety of I/O pins. Various current
sensor technologies are supported including Current Transformers (CT), Resistive Shunts, and Rogowski (di/dt) Coils.
In addition to advanced measurement functions, the real time clock function allows the 71M6511/6511H to record time of use
(TOU) metering information for multi-rate applications. Measurements can be displayed on either a 3V or a 5V LCD. Flexible
mapping of LCD display segments will facilitate integration with any LCD format. The design trade-off between the number of
LCD segments and DIO pins can be flexibly configured using memory-mapped I/O to accommodate various requirements.
The 71M6511 includes several I/O peripheral functions that improve the functionality of the device and reduce the component
count for most meter applications. The I/O peripherals include two UARTs, digital I/O, comparator inputs, LCD display drivers,
I2C interface and an optical/IR interface.
One of the two internal UARTs (UART1) is adapted to support an Infrared LED with internal drive output and sense input but it
can also function as a standard UART.
A block diagram of the chip is shown in Figure 1. A detailed description of various hardware blocks follows.
Analog Front End (AFE)
The AFE of the TERIDIAN 71M6511 Power Meter IC is comprised of an input multiplexer, a delta-sigma A/D converter with a
voltage reference, followed by an FIR filter. A block diagram of the AFE is shown in Figure 3.
Multiplexer
The input multiplexer supports four input signals that are applied to the pins IA, VA, and IB plus the output of the internal
temperature sensor. The multiplexer can be operated in two modes:
•
•
During a normal multiplexer cycle, the signals from the pins IA, VA, and IB, are selected.
During the alternate multiplexer cycle, the temperature signal (TEMP) is selected, along with the other signal sources
shown in Table 1.
Alternate multiplexer cycles are usually performed infrequently (every second or so). VA is not replaced in the alternate multiplexer cycles. Missing samples due to alternate multiplexer cycles are automatically interpolated by the CE.
EQU
Channels used from MUX
Sequence
States 0 → 3
Channels used from alternative
MUX Sequence
States 0 → 3
0
1
2
3
0
1
2
3
000
IA
VA
IB
-
TEMP
VA
-
-
001
IA
VA
IB
-
TEMP
VA
IB
-
Table 1: Inputs Selected in Regular and Alternate Multiplexer Cycles
In a typical application, the IA input is connected to a current transformer that senses the line current. VA is typically connected
to a voltage sensor through resistor dividers. IB may be connected to a second current transformer, e.g. for optional tamper
detection.
Page: 8 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
The Multiplexer Control Circuit handles the setting of the multiplexer. The function of the Multiplexer Control Circuit is governed
by the I/O RAM registers MUX_ALT (0x2005[2]), EQU (0x2000[7:5]), and MUX_DIV (0x2002[7:6]). MUX_DIV controls the
number of samples per cycle. It can request 2, 3, 4, or 6 multiplexer states per cycle.
The MUX_ALT bit requests an alternate multiplexer cycle. The bit may be asserted on any MPU cycle and may be subsequently de-asserted on any cycle including the next one. A rising edge on MUX_ALT will cause the Control Circuit to wait
until the next multiplexer cycle and implement a single alternate cycle.
Multiplexer Control Circuit also controls the FIR filter initiation and the chopping of the ADC reference voltage, VREF. The
Multiplexer Control Circuit is clocked by CK32, the 32768Hz clock from the PLL block, and launches each pass through the CE
program.
Table 2 shows the possible settings for MUX_DIV and FIR_LEN and the resulting channels sampled along with sample
frequencies.
MUX_DIV
(0x2002[7.6])
Number of
channels
selected
(mux states
per cycle)
Number of
CK32 states
for code pass
Effective
sample
frequency
[Hz]
Number of
CK32 states
for code
pass
FIR_LEN = 0
Effective
sample
frequency
[Hz]
FIR_LEN =1
00
---
Not Allowed
01
4
9
3640.89
13
2520.615
10
3
7
4681.143
10
3276.8
11
2
5
6553.6
7
4681.143
Table 2: Channel control based on MUX_DIV and FIR_LEN
ADC
A single 21/22-bit delta-sigma A/D converter (ADC) digitizes the power inputs to the AFE. The resolution of the ADC is
programmable using the I/O RAM register FIR_LEN register (0x2005[4]). ADC resolution may be selected to be 21 bits
(FIR_LEN=0), or 22 bits (FIR_LEN=1). Conversion time is two cycles of CK32 with FIR_LEN = 0 and three cycles with
FIR_LEN = 1.
In order to provide the maximum resolution, the ADC should be operated with FIR_LEN = 1. Accuracy, timing and
functional specifications in this data sheet are based on FIR_LEN = 1 and MUX_DIV = 1 (four CK32 cycles). Alternative
specifications are also provided for FIR_LEN = 1 and MUX_DIV = 2 (three CK32 cycles) in the CE Program and
Environment section.
Initiation of each ADC conversion is controlled by the Multiplexer Control Circuit as described previously.
FIR Filter
The finite impulse response (FIR) filter is an integral part of the ADC and it is optimized for use with the multiplexer. The
purpose of the FIR is to decimate the ADC output to the desired resolution. At the end of each ADC conversion, the output
data of the FIR filter (raw data) is stored into the CE DRAM location determined by the multiplexer selection. The location of
the raw data in the CE DRAM is specified in the CE Program and Environment Section.
Voltage Reference
The 71M6511/6511H includes an on-chip precision bandgap voltage reference that incorporates auto-zero techniques. The
reference of the 71M6511H is trimmed in production to minimize errors caused by component mismatch and drift. The result is
a voltage output with a predictable temperature coefficient.
Page: 9 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
The voltage reference is chopper stabilized, i.e. the polarity can be switched by the MPU using the I/O RAM register
CHOP_ENA (0x2002[5:4]). The two bits in the CHOP_ENA register enable the MPU to operate the chopper circuit in regular or
inverted operation, or in “toggling” mode. When the chopper circuit is toggled in between multiplexer cycles, DC offsets on the
measured signals will automatically be averaged out.
The general topology of a chopped amplifier is given in Figure 2.
A
Vinp
B
A
Vinn
A
+
G
-
B
Voutp
B
A
Voutn
B
CROSS
Figure 2: General Topology of a Chopped Amplifier
It is assumed that an offset voltage Voff appears at the positive amplifier input. With all switches, as controlled by CROSS in
the “A” position, the output voltage is:
Voutp – Voutn = G (Vinp + Voff – Vinn) = G (Vinp – Vinn) + G Voff
With all switches set to the “B” position by applying the inverted CROSS signal, the output voltage is:
Voutn – Voutp = G (Vinn – Vinp + Voff) = G (Vinn – Vinp) + G Voff, or
Voutp – Voutn = G (Vinp – Vinn) - G Voff
Thus, when CROSS is toggled, e.g. after each multiplexer cycle, the offset will alternately appear on the output as positive and
negative, which results in the offset effectively being eliminated, regardless of its polarity or magnitude.
The Functional Description Section contains a chapter with a detailed description on controlling the CHOP_ENA register.
Temperature Sensor
The 71M6511/6511H includes an on-chip temperature sensor implemented as a bandgap reference. It is used to determine
the die temperature The MPU may request an alternate multiplexer cycle containing the temperature sensor output by
asserting MUX_ALT.
The primary use of the temperature data is to determine the magnitude of compensation required to offset the thermal drift in
the system (see section titled “Temperature Compensation”).
The zero reference for the temperature sensor is VBIAS.
Functional Description
The AFE functions as a data acquisition system, controlled by the MPU. The main signals (IA, VA, IB) are sampled and the
ADC counts obtained are stored in CE RAM where they can be accessed by the CE and, if necessary, by the MPU. Alternate
multiplexer cycles are initiated less frequently by the MPU to gather access to the slow temperature signal.
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VREF
IA
VA
IB
VBIAS
∆Σ ADC
CONVERTER
MUX
VBIAS
V3P3A
+
FIR
FILTER
VREF
TEMP
MUX
MUX
CTRL
EQU
MUX_ALT
MUX_DIV
CHOP_EN
VREF_DIS
VREF
FIR_LEN
CK32
Figure 3: AFE Block Diagram
Computation Engine (CE)
The CE, a dedicated 32-bit RISC processor, performs the precision computations necessary to accurately measure energy.
The CE calculations and processes include:
•
Multiplication of each current sample with its associated voltage sample to obtain the energy per sample (when
multiplied with the constant sample time).
•
Frequency-insensitive delay cancellation on all six channels (to compensate for the delay between samples caused
by the multiplexing scheme).
•
90° phase shifter (for VAR calculations).
•
Pulse generation.
•
Monitoring of the input signal frequency (for frequency and phase information).
•
Monitoring of the input signal amplitude (for sag detection).
•
Scaling of the processed samples based on chip temperature (temperature compensation) and calibration
coefficients.
The CE program RAM (CE PRAM) is loaded at boot time by the MPU and then executed by the CE. Each CE instruction word
is 2 bytes long. The CE program counter begins a pass through the CE code each time multiplexer state 0 begins. The code
pass ends when a HALT instruction is executed. For proper operation, the code pass must be completed before the
multiplexer cycle ends (see System Timing Summary in the Functional Description Section).
The CE data RAM (CE DRAM) can be accessed by the FIR filter block, the RTM circuit, the CE, and the MPU. Assigned time
slots are reserved for FIR, RTM, and MPU, respectively, such that memory accesses to CE_RAM do not collide. Holding registers are used to convert 8-bit wide MPU data to/from 32-bit wide CE DRAM data, and wait states are inserted as needed,
depending on the frequency of CKMPU.
Table 3 shows the CE DRAM addresses allocated to analog inputs from the AFE.
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Address (hex)
0x00
Name
IA
Description
Phase A current
0x01
VA
Phase A voltage
0x02
IB
Phase B current
0x03
-
Reserved
0x04
-
Reserved
0x05
-
Reserved
0x06
TEMP
0x07
--
Temperature
Reserved
Table 3: CE DRAM Locations for ADC Results
Meter Equations
The Compute Engine (CE) program for residential meter configurations implements the equations in Table 4. The I/O RAM
register EQU specifies the equation to be used based on the number and arrangement of phases used for metering. In case of
single-phase metering, the unconnected input should be tied to V3P3A, the analog supply voltage. The EQU selection enables
the 71M6511 to calculate single-phase power measurement based on the type of service used. Table 4 also states the
sequence of the multiplexer in the AFE.
EQU
Channels used from MUX
Sequence
States 0 → 3
Formula
Channels used from alternative
MUX Sequence
States 0 → 3
0
1
2
3
0
1
2
3
000
VA IA
(1 element, 2W 1φ)
IA
VA
IB
-
TEMP
VA
-
-
001
VA(IA-IB)/2
(1 element, 3W 1φ)
IA
VA
IB
-
TEMP
VA
IB
-
Table 4: Standard Meter Equations (inputs shown gray are scanned but not used for calculation)
Pulse Generator
The CE contains two pulse generators which create low jitter pulses at a rate set by the CE DRAM registers
APULSEW*WRATE and APULSER*WRATE if EXT_PULSE (a CE input variable in CE DRAM) is 15. This mode puts the MPU
in control of pulse generation by placing values into the APULSEW and APULSER registers (“external pulse generation”).
If EXT_PULSE is 0, APULSEW is replaced with WSUM_X and APULSER is replaced with VARSUM_X. In this mode, the CE
generates pulse based on its internal computation of WSUM_X and VARSUM_X, the signed sums of energy from all three
elements (“internal pulse generation”).
The DIO_PV and DIO_PW bits as described in the Digital I/O section can be programmed to route WPULSE and VARPULSE
to the output pins DIO6 and DIO7 respectively. DIO6 and DIO7 can be configured to generate interrupts (useful for pulse
counting by the MPU – see On-Chip Resources (DIO Section).
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Real-Time Monitor
The CE contains a Real Time Monitor (RTM), which can be programmed to monitor four selectable CE RAM locations at full
sample rate. The four monitored locations are serially output to the TMUXOUT pin via the digital output multiplexer at the
beginning of each CE code pass (see the Test Ports Section for details)
CE Functional Overview
The ADC processes one sample per channel per multiplexer cycle. Figure 4 shows the timing of the samples taken during one
multiplexer cycle.
The number of samples processed during one accumulation cycle is controlled by the I/O RAM registers PRE_SAMPS
(0x2001[7:6]) and SUM_CYCLES (0x2001[5:0]). The integration time for each energy output is
PRE_SAMPS * SUM_CYCLES / 2520.6, where 2520.6 is the sample rate [Hz] (for MUX_DIV = 1)
For example, PRE_SAMPS = 42 and SUM_CYCLES = 50 will establish 2100 samples per accumulation cycle. PRE_SAMPS =
100 and SUM_CYCLES = 21 will result in the exact same accumulation cycle of 2100 samples or 833ms. After an
accumulation cycle is completed, the XFER_BUSY interrupt signals to the MPU that accumulated data are available.
1/32768Hz =
30.518µs
IB
IA
VA
13/32768Hz = 397µs
per mux cycle
Figure 4: Samples in Multiplexer Cycle
The end of each multiplexer cycle is signaled to the MPU by the CE_BUSY interrupt. At the end of each multiplexer cycle,
status information, such as sag data and the digitized input signal, is available to the MPU.
833ms
20ms
XFER_BUSY
Interrupt to MPU
Figure 5: Accumulation Interval
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Figure 5 shows the accumulation interval resulting from MUX_DIV = 1, PRE_SAMPS = 42 and SUM_CYCLES = 50, consisting
of 2100 samples of 397µs each, followed by the XFER_BUSY interrupt. The sampling in this example is applied to a 50Hz
signal.
There is no correlation between the line signal frequency and the choice of PRE_SAMPS or SUM_CYCLES (even though
when SUM_CYCLES = 42 one set of SUM_CYCLES happens to sample a period of 16.6ms). Furthermore, sampling does not
have to start when the line voltage crosses the zero line.
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80515 MPU Core
80515 Overview
The 71M6511/6511H includes an 80515 MPU (8-bit, 8051-compatible) that processes most instructions in one clock cycle.
Using a 5MHz clock results in a processing throughput of 5 MIPS. The 80515 architecture eliminates redundant bus states and
implements parallel execution of fetch and execution phases. Normally a machine cycle is aligned with a memory fetch, therefore, most of the 1-byte instructions are performed in a single cycle. This leads to an 8x performance (in average) improvement
(in terms of MIPS) over the Intel 8051 device running at the same clock frequency.
Actual processor clocking speed can be adjusted to the total processing demand of the application (metering calculations,
AMR management, memory management, LCD driver management and I/O management) using the I/O RAM register
MPU_DIV[2:0].
Typical measurement and metering functions based on the results provided by the internal 32-bit compute engine (CE) are
available for the MPU as part of TERIDIAN’s standard library. A standard ANSI “C” 80515-application programming interface
library is available to help reduce design cycle.
Memory Organization
The 80515 MPU core incorporates the Harvard architecture with separate code and data spaces.
Memory organization in the 80515 is similar to that of the industry standard 8051. There are three memory areas: Program
memory (Flash), external data memory (XRAM), physically consisting of XRAM, CE DRAM, CE PRAM and I/O RAM, and
internal data memory (Internal RAM). Figure 6 shows the memory map (see also Table 55).
Internal and External Data Memory: Both internal and external data memory are physically located on the 71M6511 IC. External data memory is only external to the 80515 MPU core.
0xFFFF
Flash memory
0x0000
Program memory
0xFFFF
--0x4000
0x3FFF
CE PRAM
0x3000
0x2FFF
--0x2100
0x20FF
I/O RAM
0x2000
0x1FFF
--0x1400
0x13FF
CE DRAM
0x1000
0x0FFF
--0x0800
0x07FF
XRAM
0x0000
External data memory
0xFF
SFRs, RAM,
reg. banks
0x00
Internal data memory
Figure 6: Memory Map
Program Memory: The 80515 can address up to 64KB of program memory space from 0x0000 to 0xFFFF. Program memory
is read when the MPU fetches instructions or performs a MOVC operation.
After reset, the MPU starts program execution from location 0x0000. The lower part of the program memory includes reset and
interrupt vectors. The interrupt vectors are spaced at 8-byte intervals, starting from 0x0003.
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External Data Memory: While the 80515 can address up to 64KB of external data memory in the space from 0x0000 to
0xFFFF, only the memory ranges shown in Figure 6 contain physical memory. The 80515 writes into external data memory
when the MPU executes a MOVX @Ri,A or MOVX @DPTR,A instruction. The MPU reads external data memory by executing
a MOVX A,@Ri or MOVX A,@DPTR instruction (SFR USR2 provides the upper 8 bytes for the MOVX A,@Ri instruction).
Clock Stretching: MOVX instructions can access fast or slow external RAM and external peripherals. The three low ordered
bits of the CKCON register define the stretch memory cycles. Setting all the CKCON stretch bits to one allows access to very
slow external RAM or external peripherals.
Table 5 shows how the signals of the External Memory Interface change when stretch values are set from 0 to 7. The widths of
the signals are counted in MPU clock cycles. The post-reset state of the CKCON register, which is in bold in the table,
performs the MOVX instructions with a stretch value equal to 1.
CKCON register
CKCON.2
Stretch Value
CKCON.1
CKCON.0
0
0
0
0
0
0
Read signals width
Write signal width
memaddr
memrd
memaddr
memwr
0
1
1
2
1
1
1
2
2
3
1
1
0
2
3
3
4
2
0
1
1
3
4
4
5
3
1
0
0
4
5
5
6
4
1
0
1
5
6
6
7
5
1
1
0
6
7
7
8
6
1
1
1
7
8
8
9
7
Table 5: Stretch Memory Cycle Width
There are two types of instructions, differing in whether they provide an eight-bit or sixteen-bit indirect address to the external
data RAM.
In the first type (MOVX A,@Ri), the contents of R0 or R1, in the current register bank, provide the eight lower-ordered bits of
address. The eight high-ordered bits of address are specified with the USR2 SFR. This method allows the user paged access
(256 pages of 256 bytes each) to the full 64KB of external data RAM. In the second type of MOVX instruction (MOVX
A,@DPTR), the data pointer generates a sixteen-bit address. This form is faster and more efficient when accessing very large
data arrays (up to 64 Kbytes), since no additional instructions are needed to set up the eight high ordered bits of address.
It is possible to mix the two MOVX types. This provides the user with four separate data pointers, two with direct access and
two with paged access to the entire 64KB of external memory range.
Dual Data Pointer: The Dual Data Pointer accelerates the block moves of data. The standard DPTR is a 16-bit register that is
used to address external memory or peripherals. In the 80515 core, the standard data pointer is called DPTR, the second data
pointer is called DPTR1. The data pointer select bit chooses the active pointer. The data pointer select bit is located at the LSB
of the DPS register (DPS.0). DPTR is selected when DPS.0 = 0 and DPTR1 is selected when DPS.0 = 1.
The user switches between pointers by toggling the LSB of the DPS register. All DPTR-related instructions use the currently
selected DPTR for any activity.
The second data pointer may not be supported by certain compilers.
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Internal Data Memory: The Internal data memory provides 256 bytes (0x00 to 0xFF) of data memory. The internal data
memory address is always 1 byte wide and can be accessed by either direct or indirect addressing. The Special Function
Registers occupy the upper 128 bytes. This SFR area is available only by direct addressing. Indirect addressing
accesses the upper 128 bytes of Internal RAM.
The lower 128 bytes contain working registers and bit-addressable memory. The lower 32 bytes form four banks of eight
registers (R0-R7). Two bits on the program memory status word (PSW) select which bank is in use. The next 16 bytes form a
block of bit-addressable memory space at bit addressees 0x00-0x7F. All of the bytes in the lower 128 bytes are accessible
through direct or indirect addressing. Table 6 shows the internal data memory map.
Address
0xFF
0x80
Direct addressing
Indirect addressing
Special Function Registers
(SFRs)
RAM
0x7F
Byte-addressable area
0x30
0x2F
Bit-addressable area
0x20
0x1F
Register banks R0…R7
0x00
Table 6: Internal Data Memory Map
Special Function Registers (SFRs)
A map of the Special Function Registers is shown in Table 7.
Hex\Bin
Bit-addressable
X000
F8
F0
E8
E0
D8
D0
C8
C0
B8
B0
A8
A0
98
90
88
80
Byte-addressable
X001
X010
X011
X100
X101
Bin/Hex
X110
X111
INTBITS
B
WDI
A
WDCON
PSW
IRCON
IEN1
IP1
IEN0
P2
S0CON
P1
TCON
P0
IP0
DIR2
S0BUF
DIR1
TMOD
SP
S0RELH
FLSHCTL
S0RELL
DIR0
IEN2
DPS
TL0
DPL
S1RELH
S1CON
TL1
DPH
USR2
PGADR
S1BUF
ERASE
TH0
DPL1
S1RELL
EEDATA
EECTRL
TH1
DPH1
CKCON
WDTREL
PCON
FF
F7
EF
E7
DF
D7
CF
C7
BF
B7
AF
A7
9F
97
8F
87
Table 7: Special Function Registers Locations
Only a few addresses are occupied, the others are not implemented. SFRs specific to the 651X are shown in bold print. Any
read access to unimplemented addresses will return undefined data, while any write access will have no effect. The registers at
0x80, 0x88, 0x90, etc., are bit-addressable, all others are byte-addressable.
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Special Function Registers (Generic 80515 SFRs)
Table 8 shows the location of the SFRs and the value they assume at reset or power-up.
Name
Location
Reset value
Description
P0
SP
DPL
DPH
DPL1
DPH1
WDTREL
PCON
TCON
TMOD
TL0
TL1
TH0
TH1
CKCON
P1
DPS
S0CON
S0BUF
IEN2
S1CON
S1BUF
S1RELL
P2
IEN0
IP0
S0RELL
P3
IEN1
IP1
S0RELH
S1RELH
USR2
IRCON
PSW
WDCON
A
B
0x80
0x81
0x82
0x83
0x84
0x85
0x86
0x87
0x88
0x89
0x8A
0x8B
0x8C
0x8D
0x8E
0x90
0x92
0x98
0x99
0x9A
0x9B
0x9C
0x9D
0xA0
0xA8
0xA9
0xAA
0xB0
0xB8
0xB9
0xBA
0xBB
0xBF
0xC0
0xD0
0xD8
0xE0
0xF0
0xFF
0x07
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x01
0xFF
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0x00
0xD9
0xFF
0x00
0x00
0x03
0x03
0x00
0x00
0x00
0x00
0x00
0x00
Port 0
Stack Pointer
Data Pointer Low 0
Data Pointer High 0
Data Pointer Low 1
Data Pointer High 1
Watchdog Timer Reload register
UART Speed Control
Timer/Counter Control
Timer Mode Control
Timer 0, low byte
Timer 1, high byte
Timer 0, low byte
Timer 1, high byte
Clock Control (Stretch=1)
Port 1
Data Pointer select Register
Serial Port 0, Control Register
Serial Port 0, Data Buffer
Interrupt Enable Register 2
Serial Port 1, Control Register
Serial Port 1, Data Buffer
Serial Port 1, Reload Register, low byte
Port 2
Interrupt Enable Register 0
Interrupt Priority Register 0
Serial Port 0, Reload Register, low byte
Port 3
Interrupt Enable Register 1
Interrupt Priority Register 1
Serial Port 0, Reload Register, high byte
Serial Port 1, Reload Register, high byte
User 2 Port, high address byte for MOVX@Ri
Interrupt Request Control Register
Program Status Word
Baud Rate Control Register (only WDCON.7 bit used)
Accumulator
B Register
Table 8: Special Function Registers Reset Values
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Accumulator (ACC, A): ACC is the accumulator register. Most instructions use the accumulator to hold the operand. The
mnemonics for accumulator-specific instructions refer to accumulator as “A”, not ACC.
B Register: The B register is used during multiply and divide instructions. It can also be used as a scratch-pad register to hold
temporary data.
Program Status Word (PSW):
MSB
LSB
CV
AC
F0
RS1
RS
OV
-
P
Table 9: PSW Register Flags
Bit
Symbol
Function
PSW.7
CV
Carry flag
PSW.6
AC
Auxiliary Carry flag for BCD operations
PSW.5
F0
General purpose Flag 0 available for user. Not to be confused with the F0 flag
in the CE STATUS register.
PSW.4
RS1
PSW.3
RS0
Register bank select control bits. The contents of RS1 and RS0 select the working
register bank:
RS1/RS0
Bank selected
Location
00
Bank 0
(0x00 – 0x07)
01
Bank 1
(0x08 – 0x0F)
10
Bank 2
(0x10 – 0x17)
11
Bank 3
(0x18 – 0x1F)
PSW.2
OV
Overflow flag
PSW.1
-
User defined flag
PSW.0
P
Parity flag, affected by hardware to indicate odd / even number of “one” bits in the
Accumulator, i.e. even parity.
Table 10: PSW bit functions
Stack Pointer (SP): The stack pointer is a 1-byte register initialized to 0x07 after reset. This register is incremented before
PUSH and CALL instructions, causing the stack to begin at location 0x08.
Data Pointer: The data pointer (DPTR) is 2 bytes wide. The lower part is DPL, and the highest is DPH. It can be loaded as a
2-byte register (MOV DPTR,#data16) or as two registers (e.g. MOV DPL,#data8). It is generally used to access external code
or data space (e.g. MOVC A,@A+DPTR or MOVX A,@DPTR respectively).
Program Counter: The program counter (PC) is 2 bytes wide initialized to 0x0000 after reset. This register is incremented
during the fetching operation code or when operating on data from program memory.
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Port Registers: The I/O ports are controlled by Special Function Registers P0, P1, and P2. The contents of the SFR can be
observed on corresponding pins on the chip. Writing a ‘1’ to any of the ports (see Table 11) causes the corresponding pin to be
at high level (V3P3), and writing a ‘0’ causes the corresponding pin to be held at low level (GND). The data direction registers
DIR0, DIR1, and DIR2 define individual pins as input or output pins (see section On-Chip Resources – DIO Ports for details).
Register
SFR
Address
R/W
Description
P0
DIR0
0x80
0xA2
R/W
R/W
P1
DIR1
P2
DIR2
0x90
0x91
0xA0
0xA1
R/W
R/W
R/W
R/W
Register for port 0 read and write operations (pins DIO4…DIO7)
Data direction register for port 0. Setting a bit to 1 means that the corresponding pin is
an output.
Register for port 1 read and write operations (pins DIO8…DIO14)
Data direction register for port 1.
Register for port 2 read and write operations (pins DIO17)
Data direction register for port 2.
Table 11: Port Registers
All four ports on the chip are bi-directional. Each of them consists of a Latch (SFR ‘P0’ to ‘P3’), an output driver, and an input
buffer, therefore the MPU can output or read data through any of these ports. Even if a DIO pin is configured as an output, the
state of the pin can still be read by the MPU, for example when counting pulses issued via DIO pins that are under CE control.
Special Function Registers Specific to the 71M6511
Table 12 shows the location and description of the 71M6511-specific SFRs.
Register
ERASE
Alternative
Name
SFR
Address
R/W
FLSH_ERASE
0x94
W
Description
This register is used to initiate either the Flash Mass Erase cycle or
the Flash Page Erase cycle. Specific patterns are expected for
FLSH_ERASE in order to initiate the appropriate Erase cycle (default
= 0x00).
0x55 – Initiate Flash Page Erase cycle. Must be proceeded by a write
to FLSH_PGADR @ SFR 0xB7.
0xAA – Initiate Flash Mass Erase cycle. Must be proceeded by a
write to FLSH_MEEN @ SFR 0xB2 and the debug port must
be enabled.
Any other pattern written to FLSH_ERASE will have no effect.
PGADDR
FLSH_PGADR
EEDATA
EECTRL
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0xB7
R/W
0x9E
0x9F
R/W
R/W
Flash Page Erase Address register containing the flash memory page
address (page 0 thru 127) that will be erased during the Page Erase
cycle (default = 0x00).
Must be re-written for each new Page Erase cycle.
I2C EEPROM interface data register
I2C EEPROM interface control register. If the MPU wishes to write a
byte of data to EEPROM, it places the data in EEDATA and then
writes the ‘Transmit’ code to EECTRL. The write to EECTRL initiates
the transmit sequence. See the section I2C Interface (EEPROM) for
a description of the command and status bits available for EECTRL.
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FLSHCRL
0xB2
R/W
W
R/W
R
WDI
0xE8
R/W
R/W
W
INTBITS
INT0…INT6
0xF8
R
Bit 0 (FLSH_PWE): Program Write Enable:
0 – MOVX commands refer to XRAM Space, normal operation
(default).
1 – MOVX @DPTR,A moves A to Program Space (Flash) @
DPTR.
This bit is automatically reset after each byte written to flash. Writes
to this bit are inhibited when interrupts are enabled.
Bit 1 (FLSH_MEEN): Mass Erase Enable:
0 – Mass Erase disabled (default).
1 – Mass Erase enabled.
Must be re-written for each new Mass Erase cycle.
Bit 6 (SECURE):
Enables security provisions that prevent external reading of flash
memory and CE program RAM. This bit is reset on chip reset and
may only be set. Attempts to write zero are ignored.
Bit 7 (PREBOOT):
Indicates that the preboot sequence is active.
Only byte operations on the whole WDI register should be used
when writing. The byte must have all bits set except the bits that are
to be cleared.
The multi-purpose register WDI contains the following bits:
Bit 0 (IE_XFER): XFER Interrupt Flag:
This flag monitors the XFER_BUSY interrupt. It is set by hardware
and must be cleared by the interrupt handler
Bit 1 (IE_RTC): RTC Interrupt Flag:
This flag monitors the RTC_1SEC interrupt. It is set by hardware and
must be cleared by the interrupt handler
Bit 7 (WD_RST): WD Timer Reset:
The WDT is reset when a 1 is written to this bit.
Interrupt inputs. The MPU may read these bits to see the input to
external interrupts INT0, INT1, up to INT6. These bits do not have
any memory and are primarily intended for debug use
Table 12: Special Function Registers
Instruction Set
All instructions of the generic 8051 microcontroller are supported. A complete list of the instruction set and of the associated
op-codes is contained in the 651X Software User’s Guide (SUG).
UART
The 71M6511 includes a UART (UART0) that can be programmed to communicate with a variety of AMR modules. A second
UART (UART1) is connected to the optical port, as described in the optical port description.
The UART is a dedicated 2-wire serial interface, which can communicate with an external host processor at up to 38,400 bits/s
((with MPU clock = 1.2288MHz). The operation of each pin is as follows:
RX: Serial input data are applied at this pin. Conforming to RS-232 standard, the bytes are input LSB first. The voltage applied
at RX must not exceed 3.6V.
TX: This pin is used to output the serial data. The bytes are output LSB first.
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The 71M6511 has several UART-related registers, which can be read and written. All UART transfers are programmable for
parity enable, parity, 2 stop bits/1 stop bit and XON/XOFF options for variable communication baud rates from 300 to 38400
bps. Table 13 shows how the baud rates are calculated. Table 14 shows the selectable UART operation modes.
Using Timer 1
Serial Interface 0
smod
2
Using Internal Baud Rate Generator
2smod * fCKMPU/(64 * (210-S0REL))
* fCKMPU/ (384 * (256-TH1))
Serial Interface 1
fCKMPU/(32 * (210-S1REL))
N/A
Note: S0REL and S1REL are 10-bit values derived by combining bits from the respective timer reload registers. SMOD is the
SMOD bit in the SFR PCON. TH1 is the high byte of timer 1.
Table 13: Baud Rate Generation
UART 0
UART 1
Mode 0
N/A
Start bit, 8 data bits, parity, stop bit, variable
baud rate (internal baud rate generator)
Mode 1
Start bit, 8 data bits, stop bit,
variable baud rate (internal baud
rate generator or timer 1)
Start bit, 8 data bits, stop bit, variable baud rate
(internal baud rate generator)
Mode 2
Start bit, 8 data bits, parity, stop bit,
fixed baud rate 1/32 or 1/64 of fCKMPU
N/A
Mode 3
Start bit, 8 data bits, parity, stop bit,
variable baud rate (internal baud
rate generator or timer 1)
N/A
Table 14: UART Modes
Parity of serial data is available through the P flag of the accumulator. Seven-bit serial modes with parity, such as those used
by the FLAG protocol, can be simulated by setting and reading bit 7 of 8-bit output data. Seven-bit serial modes without parity
can be simulated by setting bit 7 to a constant 1. 8-bit serial modes with parity can be simulated by setting and reading the 9th
bit, using the control bits TB80 (S0CON.3) and TB81 (S1CON.3) in the S0COn and S1CON SFRs for transmit and RB81
(S1CON.2) for receive operations. SM20 (S0CON.5) and SM21 (S1CON.5) can be used as handshake signals for inter-processor communication in multi-processor systems.
Serial Interface 0 Control Register (S0CON).
The function of the UART0 depends on the setting of the Serial Port Control Register S0CON.
MSB
SM0
LSB
SM1
SM20
REN0
TB80
RB80
TI0
RI0
Table 15: The S0CON Register
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Serial Interface 1 Control Register (S1CON).
The function of the serial port depends on the setting of the Serial Port Control Register S1CON.
MSB
LSB
SM
-
SM21
REN1
TB81
RB81
TI1
RI1
Table 16: The S1CON register
Bit
S0CON.7
S0CON.6
Symbol
SM0
SM1
Function
These two bits set the UART0 mode:
Mode
Description
SM0
0
N/A
0
SM1
0
1
8-bit UART
0
1
2
9-bit UART
1
0
3
9-bit UART
1
1
S0CON.5
SM20
Enables the inter-processor communication feature.
S0CON.4
REN0
If set, enables serial reception. Cleared by software to disable reception.
S0CON.3
TB80
The 9th transmitted data bit in Modes 2 and 3. Set or cleared by the
MPU, depending on the function it performs (parity check, multiprocessor
communication etc.)
S0CON.2
RB80
In Modes 2 and 3 it is the 9th data bit received. In Mode 1, if SM20 is 0,
RB80 is the stop bit. In Mode 0 this bit is not used. Must be cleared by
software
S0CON.1
TI0
Transmit interrupt flag, set by hardware after completion of a serial
transfer. Must be cleared by software.
S0CON.0
RI0
Receive interrupt flag, set by hardware after completion of a serial
reception. Must be cleared by software
Table 17: The S0CON Bit Functions
Note: The speed in Mode 2 depends on the SMOD bit in the SFR PCON. See the PCON register description.
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Bit
Symbol
S1CON.7
SM
Function
Sets the baud rate for UART1
SM
Mode
Description
Baud Rate
0
A
9-bit UART
variable
1
B
8-bit UART
variable
S1CON.5
SM21
Enables the inter-processor communication feature.
S1CON.4
REN1
If set, enables serial reception. Cleared by software to disable reception.
S1CON.3
TB81
The 9th transmitted data bit in Mode A. Set or cleared by the MPU,
depending on the function it performs (parity check, multiprocessor
communication etc.)
S1CON.2
RB81
In Modes 2 and 3, it is the 9th data bit received. In Mode B, if sm21 is 0,
rb81 is the stop bit. Must be cleared by software
S1CON.1
TI1
Transmit interrupt flag, set by hardware after completion of a serial
transfer. Must be cleared by software.
S1CON.0
RI1
Receive interrupt flag, set by hardware after completion of a serial
reception. Must be cleared by software
Table 18: The S1CON Bit Functions
Timers and Counters
The 80515 has two 16-bit timer/counter registers: Timer 0 and Timer 1. These registers can be configured for counter or timer
operations.
In timer mode, the register is incremented every machine cycle meaning that it counts up after every 12 periods of the MPU
clock signal.
In counter mode, the register is incremented when the falling edge is observed at the corresponding input signal T0 or T1 (T0
and T1 are the timer gating inputs derived from certain DIO pins, see the DIO Ports chapter). Since it takes 2 machine cycles
to recognize a 1-to-0 event, the maximum input count rate is 1/2 of the oscillator frequency. There are no restrictions on the
duty cycle, however to ensure proper recognition of 0 or 1 state, an input should be stable for at least 1 machine cycle.
Four operating modes can be selected for Timer 0 and Timer 1. Two Special Function Registers (TMOD and TCON) are used
to select the appropriate mode.
Timer/Counter Mode Control register (TMOD):
MSB
GATE
LSB
C/T
M1
Timer 1
M0
GATE
C/T
M1
Timer 0
M0
Table 19: The TMOD Register
Bits TR1 (TCON.6) and TR0 (TCON.4) in the TCON register (see Table 22 and Table 23) start their associated timers when
set.
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Bit
Symbol
Function
TMOD.7
TMOD.3
Gate
If set, enables external gate control (pin int0 or int1 for Counter 0 or 1,
respectively). When int0 or int1 is high, and TRX bit is set (see TCON register), a
counter is incremented every falling edge on t0 or t1 input pin
TMOD.6
TMOD.2
C/T
Selects Timer or Counter operation. When set to 1, a Counter operation is
performed. When cleared to 0, the corresponding register will function as a Timer.
TMOD.5
TMOD.1
M1
Selects the mode for Timer/Counter 0 or Timer/Counter 1, as shown in TMOD
description.
TMOD.4
TMOD.0
M0
Selects the mode for Timer/Counter 0 or Timer/Counter 1, as shown in TMOD
description.
Table 20: TMOD Register Bit Description
M1
M0
Mode
Function
0
0
Mode 0
13-bit Counter/Timer with 5 lower bits in the TL0 or TL1 register and the
remaining 8 bits in the TH0 or TH1 register (for Timer 0 and Timer 1,
respectively). The 3 high order bits of TL0 and TL1 are held at zero.
0
1
Mode 1
16-bit Counter/Timer.
1
0
Mode2
8-bit auto-reload Counter/Timer. The reload value is kept in TH0 or TH1,
while TL0 or TL1 is incremented every machine cycle. When TL(x)
overflows, a value from TH(x) is copied to TL(x).
1
1
Mode3
If Timer 1 M1 and M0 bits are set to '1', Timer 1 stops. If Timer 0 M1 and M0
bits are set to '1', Timer 0 acts as two independent 8-bit Timer/Counters.
Table 21: Timers/Counters Mode Description
Note:
TL0 is affected by TR0 and gate control bits, and sets TF0 flag on overflow.
TH0 is affected by TR1 bit, and sets TF1 flag on overflow.
Timer/Counter Control Register (TCON)
MSB
TF1
LSB
TR1
TF0
TR0
IE1
IT1
IE0
IT0
Table 22: The TCON Register
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Bit
Symbol
Function
TCON.7
TF1
The Timer 1 overflow flag is set by hardware when Timer 1 overflows. This flag
can be cleared by software and is automatically cleared when an interrupt is
processed.
TCON.6
TR1
Timer 1 Run control bit. If cleared, Timer 1 stops.
TCON.5
TF0
Timer 0 overflow flag set by hardware when Timer 0 overflows. This flag can be
cleared by software and is automatically cleared when an interrupt is processed.
TCON.4
TR0
Timer 0 Run control bit. If cleared, Timer 0 stops.
TCON.3
IE1
Interrupt 1 edge flag is set by hardware when the falling edge on external pin
int1 is observed. Cleared when an interrupt is processed.
TCON.2
IT1
Interrupt 1 type control bit. Selects either the falling edge or low level on input
pin to cause an interrupt.
TCON.1
IE0
Interrupt 0 edge flag is set by hardware when the falling edge on external pin
int0 is observed. Cleared when an interrupt is processed.
TCON.0
IT0
Interrupt 0 type control bit. Selects either the falling edge or low level on input
pin to cause interrupt.
Table 23: The TCON Register Bit Functions
Table 24 specifies the combinations of operation modes allowed for timer 0 and timer 1:
Timer 1
Mode 0
Mode 1
Mode 2
Timer 0 - mode 0
YES
YES
YES
Timer 0 - mode 1
YES
YES
YES
Timer 0 - mode 2
Not allowed
Not allowed
YES
Table 24: Timer Modes
Timer/Counter Mode Control register (PCON):
MSB
LSB
SMOD
Table 25: The PCON Register
The SMOD bit in the PCON register doubles the baud rate when set.
WD Timer (Software Watchdog Timer)
The software watchdog timer is a 16-bit counter that is incremented once every 24 or 384 clock cycles. After a reset, the
watchdog timer is disabled and all registers are set to zero. The watchdog consists of a 16-bit counter (WDT), a reload register
(WDTREL), prescalers (by 2 and by 16), and control logic. Once the watchdog is started, it cannot be stopped unless the
internal reset signal becomes active.
Note: It is recommended to use the hardware watchdog timer instead of the software watchdog timer.
WD Timer Start Procedure: The WDT is started by setting the SWDT flag. When the WDT register enters the state 0x7CFF,
an asynchronous WDTS signal will become active. The signal WDTS sets bit 6 in the IP0 register and requests a reset state.
WDTS is cleared either by the reset signal or by changing the state of the WDT timer.
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Refreshing the WD Timer: The watchdog timer must be refreshed regularly to prevent the reset request signal from becoming
active. This requirement imposes an obligation on the programmer to issue two instructions. The first instruction sets WDT and
the second instruction sets SWDT. The maximum delay allowed between setting WDT and SWDT is 12 clock cycles. If this
period has expired and SWDT has not been set, WDT is automatically reset, otherwise the watchdog timer is reloaded with the
content of the WDTREL register and WDT is automatically reset. Since the WDT requires exact timing, firmware needs to be
designed with special care in order to avoid unwanted WDT resets. TERIDIAN strongly discourages the use of the software
WDT.
Special Function Registers for the WD Timer
Interrupt Enable 0 Register (IEN0):
MSB
LSB
EAL
WDT
ET2
ES0
ET1
EX1
ET0
EX0
Table 26: The IEN0 Register (see also Table 34)
Bit
Symbol
IEN0.6
WDT
Function
Watchdog timer refresh flag.
Set to initiate a refresh of the watchdog timer. Must be set directly before SWDT
is set to prevent an unintentional refresh of the watchdog timer. WDT is reset by
hardware 12 clock cycles after it has been set.
Table 27: The IEN0 Bit Functions (see also Table 34)
Note: The remaining bits in the IEN0 register are not used for watchdog control
Interrupt Enable 1 Register (IEN1):
MSB
LSB
EXEN2
SWDT
EX6
EX5
EX4
EX3
EX2
Table 28: The IEN1 Register (see also Tables 35/36)
Bit
Symbol
IEN1.6
SWDT
Function
Watchdog timer start/refresh flag.
Set to activate/refresh the watchdog timer. When directly set after setting WDT, a
watchdog timer refresh is performed. Bit SWDT is reset by the hardware 12 clock
cycles after it has been set.
Table 29: The IEN1 Bit Functions (see also Tables 35/36)
Note: The remaining bits in the IEN1 register are not used for watchdog control
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Interrupt Priority 0 Register (IP0):
MSB
LSB
--
WDTS
IP0.5
IP0.4
IP0.3
IP0.2
IP0.1
IP0.0
Table 30: The IP0 Register (see also Table 46)
Bit
Symbol
IP0.6
WDTS
Function
Watchdog timer status flag. Set when the watchdog timer was started. Can be
read by software.
Table 31: The IP0 bit Functions (see also Table 46)
Note: The remaining bits in the IP0 register are not used for watchdog control
Watchdog Timer Reload Register (WDTREL):
MSB
LSB
7
6
5
4
3
2
1
0
Table 32: The WDTREL Register
Bit
Symbol
Function
WDTREL.7
7
Prescaler select bit. When set, the watchdog is clocked through an additional
divide-by-16 prescaler
WDTREL.6
to
WDTREL.0
6-0
Seven bit reload value for the high-byte of the watchdog timer. This value is
loaded to the WDT when a refresh is triggered by a consecutive setting of bits
WDT and SWDT.
Table 33: The WDTREL Bit Functions
The WDTREL register can be loaded and read at any time.
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Interrupts
The 80515 provides 11 interrupt sources with four priority levels. Each source has its own request flag(s) located in a special
function register (TCON, IRCON, and SCON). Each interrupt requested by the corresponding flag can be individually enabled
or disabled by the enable bits in SFRs IEN0, IEN1, and IEN2.
External interrupts are the interrupts external to the 80515 core, i.e. signals that originate in other parts of the 71M6511/6511H,
for example the CE, DIO, RTC EEPROM interface, comparators.
Interrupt Overview: When an interrupt occurs, the MPU will vector to the predetermined address as shown in Table 51. Once
interrupt service has begun, it can be interrupted only by a higher priority interrupt. The interrupt service is terminated by a
return from instruction, "RETI". When a RETI instruction is performed, the processor will return to the instruction that would
have been next when the interrupt occurred.
When the interrupt condition occurs, the processor will also indicate this by setting a flag bit. This bit is set regardless of
whether the interrupt is enabled or disabled. Each interrupt flag is sampled once per machine cycle, then samples are polled
by the hardware. If the sample indicates a pending interrupt when the interrupt is enabled, then the interrupt request flag is set.
On the next instruction cycle, the interrupt will be acknowledged by hardware forcing an LCALL to the appropriate vector
address, if the following conditions are met:
•
No interrupt of equal or higher priority is already in progress.
•
An instruction is currently being executed and is not completed.
•
The instruction in progress is not RETI or any write access to the registers IEN0, IEN1, IEN2, IP0 or IP1.
Interrupt response will require a varying amount of time depending on the state of the MPU when the interrupt occurs. If the
MPU is performing an interrupt service with equal or greater priority, the new interrupt will not be invoked. In other cases, the
response time depends on the current instruction. The fastest possible response to an interrupt is 7 machine cycles. This
includes one machine cycle for detecting the interrupt and six cycles to perform the LCALL.
Special Function Registers for Interrupts:
Interrupt Enable 0 register (IE0)
MSB
LSB
EAL
WDT
ES0
ET1
EX1
ET0
EX0
Table 34: The IEN0 Register
Bit
Symbol
Function
IEN0.7
EAL
EAL=0 – disable all interrupts
IEN0.6
WDT
Not used for interrupt control
IEN0.5
-
IEN0.4
ES0
ES0=0 – disable serial channel 0 interrupt
IEN0.3
ET1
ET1=0 – disable timer 1 overflow interrupt
IEN0.2
EX1
EX1=0 – disable external interrupt 1
IEN0.1
ET0
ET0=0 – disable timer 0 overflow interrupt
IEN0.0
EX0
EX0=0 – disable external interrupt 0
Table 35: The IEN0 Bit Functions
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Interrupt Enable 1 Register (IEN1)
MSB
LSB
SWDT
EX6
EX5
EX4
EX3
EX2
Table 36: The IEN1 Register
Bit
Symbol
Function
IEN1.7
-
IEN1.6
SWDT
Not used for interrupt control
IEN1.5
EX6
EX6=0 – disable external interrupt 6
IEN1.4
EX5
EX5=0 – disable external interrupt 5
IEN1.3
EX4
EX4=0 – disable external interrupt 4
IEN1.2
EX3
EX3=0 – disable external interrupt 3
IEN1.1
EX2
EX2=0 – disable external interrupt 2
IEN1.0
Table 37: The IEN1 Bit Functions
Interrupt Enable 2 register (IE2)
MSB
LSB
-
-
-
-
-
-
-
ES1
Table 38: The IEN2 Register
Bit
Symbol
IEN2.0
ES1
Function
ES1=0 – disable serial channel 1 interrupt
Table 39: The IEN2 Bit Functions
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Timer/Counter Control register (TCON)
MSB
LSB
TF1
TR1
TF0
TR0
IE1
IT1
IE0
IT0
Table 40: The TCON Register
Bit
Symbol
Function
TCON.7
TF1
Timer 1 overflow flag
TCON.6
TR1
Not used for interrupt control
TCON.5
TF0
Timer 0 overflow flag
TCON.4
TR0
Not used for interrupt control
TCON.3
IE1
External interrupt 1 flag
TCON.2
IT1
External interrupt 1 type control bit
TCON.1
IE0
External interrupt 0 flag
TCON.0
IT0
External interrupt 0 type control bit
Table 41: The TCON Bit Functions
Interrupt Request register (IRCON)
MSB
LSB
EX6
IEX5
IEX4
IEX3
IEX2
Table 42: The IRCON Register
Bit
IRCON.7
Symbol
Function
-
IRCON.6
-
IRCON.5
IEX6
External interrupt 6 edge flag
IRCON.4
IEX5
External interrupt 5 edge flag
IRCON.3
IEX4
External interrupt 4 edge flag
IRCON.2
IEX3
External interrupt 3 edge flag
IRCON.1
IEX2
External interrupt 2 edge flag
IRCON.0
Table 43: The IRCON Bit Functions
Note: Only TF0 and TF1 (timer 0 and timer 1 overflow flag) will be automatically cleared by hardware when the service routine
is called (Signals T0ACK and T1ACK – port ISR – active high when the service routine is called).
External Interrupts
The external interrupts are connected as shown in Table 44. The polarity of interrupts 2 and 3 is programmable in the MPU.
Interrupts 2 and 3 should be programmed for falling sensitivity. The generic 8051 MPU literature states that interrupts 4
through 6 are defined as rising edge sensitive. Thus, the hardware signals attached to interrupts 5 and 6 are inverted to
achieve the edge polarity shown in Table 44.
SFR (special function register) enable bits must be set to permit any of these interrupts to occur. Likewise, each interrupt has
its own flag bit that is set by the interrupt hardware and is reset automatically by the MPU interrupt handler (0 through 5).
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XFER_BUSY and RTC_1SEC, which are OR-ed together, have their own enable and flag bits in addition to the interrupt 6
enable and flag bits (see Table 45), and these interrupts must be cleared by the MPU software.
External
Interrupt
Connection
Polarity
Flag Reset
0
Digital I/O High Priority
see DIO_Rx
automatic
1
Digital I/O Low Priority
see DIO_Rx
automatic
2
Comparator 2 or 3
falling
automatic
3
CE_BUSY
falling
automatic
4
Comparator 2 or 3
rising
automatic
5
EEPROM busy
falling
automatic
6
XFER_BUSY OR RTC_1SEC
falling
manual
Table 44: External MPU Interrupts
Interrupt 6 is edge-sensitive. The RTC_1SEC interrupt from the RTC and the XFER_BUSY interrupt from the CE are combined
using a logic OR function and the result is routed into interrupt 6. Therefore, both flags must be cleared at least once during
initialization, and both flags must always be cleared before exiting the interrupt service routine (ISR) for interrupt 6.
Note 1: If clearing of both flags is not performed, then no edge can occur to trigger interrupt 6 later resulting in the ISR for the
XFER_BUSY ceasing to run.
Note 2: Clearing both flags reliably requires some care. Either flag can be set by hardware while interrupt 6 code is running on
behalf of the other interrupt. In this situation, the unprocessed interrupt can create a lockout condition similar to the one in note
1. To prevent this lockout one must always process both interrupt flags in the same service routine.
Note 3: After a reset from an in-circuit emulator, the IE_XFER flag may not be cleared because the CE may continue to run.
The flags for the RTC_1SEC and the XFER_BUSY interrupts are located in the WDI SFR (address 0xE8).
Enable Bit
Description
Flag Bit
Description
EX0
Enable external interrupt 0
IE0
External interrupt 0 flag
EX1
Enable external interrupt 1
IE1
External interrupt 1 flag
EX2
Enable external interrupt 2
IEX2
External interrupt 2 flag
EX3
Enable external interrupt 3
IEX3
External interrupt 3 flag
EX4
Enable external interrupt 4
IEX4
External interrupt 4 flag
EX5
Enable external interrupt 5
IEX5
External interrupt 5 flag
EX6
Enable external interrupt 6
IEX6
External interrupt 6 flag
EX_XFER
EX_RTC
Enable XFER_BUSY interrupt
Enable RTC_1SEC interrupt
IE_XFER
IE_RTC
XFER_BUSY interrupt flag
RTC_1SEC interrupt flag
Table 45: Control Bits for External Interrupts
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Interrupt Priority Level Structure
All interrupt sources are combined in groups, as shown in Table 46:
Group
0
External interrupt 0
Serial channel 1 interrupt
1
Timer 0 interrupt
-
External interrupt 2
2
External interrupt 1
-
External interrupt 3
3
Timer 1 interrupt
-
External interrupt 4
4
Serial channel 0 interrupt
-
External interrupt 5
5
-
-
External interrupt 6
Table 46: Priority Level Groups
Each group of interrupt sources can be programmed individually to one of four priority levels by setting or clearing one bit in the
special function register IP0 and one in IP1. If requests of the same priority level are received simultaneously, an internal
polling sequence as per Table 50 determines which request is serviced first.
IEN enable bits must be set to permit any of these interrupts to occur. Likewise, each interrupt has its own flag bit that is set by
the interrupt hardware and is reset automatically by the MPU interrupt handler (0 through 5). XFER_BUSY and RTC_1SEC,
which are OR-ed together, have their own enable and flag bits in addition to the interrupt 6 enable and flag bits (see Table 45),
and these interrupts must be cleared by the MPU software.
An overview of the interrupt structure is given in Figure 7.
Interrupt Priority 0 Register (IP0)
MSB
LSB
--
WDTS
IP0.5
IP0.4
IP0.3
IP0.2
IP0.1
IP0.0
Table 47: The IP0 Register:
Note: WDTS is not used for interrupt controls
Interrupt Priority 1 Register (IP1)
MSB
LSB
-
-
IP1.5
IP1.4
IP1.3
IP1.2
IP1.1
IP1.0
Table 48: The IP1 Register:
IP1.x
IP0.x
Priority Level
0
0
Level0 (lowest)
0
1
Level1
1
0
Level2
1
1
Level3 (highest)
Table 49: Priority Levels
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External interrupt 0
Serial channel 1 interrupt
Timer 0 interrupt
Polling sequence
External interrupt 2
External interrupt 1
External interrupt 3
Timer 1 interrupt
External interrupt 4
Serial channel 0 interrupt
External interrupt 5
External interrupt 6
Table 50: Interrupt Polling Sequence
Interrupt Sources and Vectors
Table 51 shows the interrupts with their associated flags and vector addresses.
Interrupt Request Flag
Description
Interrupt Vector Address
IE0
External interrupt 0
0x0003
TF0
Timer 0 interrupt
0x000B
IE1
External interrupt 1
0x0013
TF1
Timer 1 interrupt
0x001B
RI0/TI0
Serial channel 0 interrupt
0x0023
RI1/TI1
Serial channel 1 interrupt
0x0083
IEX2
External interrupt 2
0x004B
IEX3
External interrupt 3
0x0053
IEX4
External interrupt 4
0x005B
IEX5
External interrupt 5
0x0063
IEX6
External interrupt 6
0x006B
Table 51: Interrupt Vectors
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DIO
External
I nt er rup t
Flags
Internal
I n t err up t
Flags
Lo gi c and
Polarity
Selec tion
I nt e rru pt
Control
R eg i s t e r
I nt er rup t
Enable
IEN0.7
IEN0.0
Priority
A s s i g nm e nt
IE0
IEN2.0
RI1
UART1
(optical)
IP1.0/
IP0.0
>=1
TI1
IEN0.1
TF0
Timer 0
IEN1.1
I2FR
Comparators
INT2
DIO
IE1
IP1.1/
IP0.1
Polling Sequen ce
Source
I nt er rup t
Vector
IRCON.1
IEN0.2
I3FR
CE_BUSY
IEN1.2
INT3
IP1.2/
IP0.2
IRCON.2
IEN0.3
Timer 1
TF1
IEN1.3
Comparators
INT4
IRCON.3
IEN0.4
RI0
UART0
>=1
TI0
IEN1.4
EEPROM/
I2C
IP1.3/
IP0.3
INT5
IP1.4/
IP0.4
IRCON.4
IEN1.5
INT6
IRCON.5
IP1.5/
IP0.5
XFER_BUSY
RTC_1S
>=1
Figure 7: Interrupt Structure
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On-Chip Resources
DIO Ports
The 71M6511/6511H includes up to 12 pins of general purpose digital I/O. These pins are dual function and can alternatively
be used as LCD drivers. Figure 8 shows a block diagram of the DIO section.
On reset or power-up, all DIO pins are inputs until they are configured for the desired direction. The pins are configured and
controlled by the DIO and DIO_DIR registers (SFRs) and by the five bits of the I/O register LCD_NUM (0x2020[4:0]). See the
description for LCD_NUM in the I/O RAM Section for a table listing the available segment pins versus DIO pins, depending on
the selection for LCD_NUM. Generally, increasing the value for LCD_NUM will configure an increasing number of general
purpose pins to be LCD segment pins, starting at the higher pin numbers.
LCD DISPLAY
DRIVER
COM0..3
SEG0..SEG2
SEG8..SEG19
LCD_NUM
LCD_MODE
LCD_CLK
LCD_EN
DIGITAL I/O
DIO_EEX
PULSEV/W
DIO_IN
DIO_OUT
LCD_NUM
DIO_GP
SEG24/DIO4 ...
SEG31/DIO11
SEG34/DIO14 ...
SEG37/DIO17
SEG3/SCLK
SEG4/SSDATA
SEG5/SFR
SEG6/SRDY
SEG7/
MUX_SYNC
Figure 8: DIO Ports Block Diagram
Each pin declared as DIO can be configured independently as an input or output with the bits of the DIO_DIRn registers. Table
52 lists the direction registers and configurability associated with each group of DIO pins. Table 53 shows the configuration for
a DIO pin through its associated bit in its DIO_DIR register.
DIO
Pin number
Data Register bit
Direction Register
bit
Internal Resources
Configurable
DIO
Pin number
Data Register bit
Direction Register
bit
Internal Resources
Configurable
0
---
2
3
4
5
6
--37 38 39
--4
5
6
DIO0=P0 (SFR 0x80)
---4
5
6
DIO_DIR0 (SFR 0xA2)
7
40
7
8
41
0
7
0
--
--
Y
Y
Y
16
22
0
17
12
1
18 19 20 21 22
----------DIO2=P2 (SFR 0xA0)
1
-----DIO_DIR2 (SFR 0xA1)
23
---
N
--
--
0
N
1
---
--
--
--
--
Y
--
Y
--
--
9
42
1
10 11 12 13
43 44
--2
3
--DIO1=P1 (SFR 0x90)
1
2
3
--DIO_DIR1 (SFR 0x91)
14
20
6
15
21
7
6
7
Y
N
N
Y
Y
--
--
--
Table 52: Data/Direction Registers and Internal Resources for DIO Pin Groups
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DIO_DIR bit
DIO Pin Function
0
1
input
output
Table 53: DIO_DIR Control Bit
Values read from and written into the DIO ports use the data registers P0, P1 and P2.
A 3-bit configuration word, I/O RAM register, DIO_Rx (0x2009[2:0] through 0x200E[6:4]) can be used for certain pins, when
configured as DIO, to individually assign an internal resource such as an interrupt or a timer control (see Table 52 for DIO pins
available for this option). This way, DIO pins can be tracked even if they are configured as outputs. This feature is useful for
pulse counting. The control resources selectable for the DIO pins are listed in Table 54. If more than one input is connected to
the same resource, the resources are combined using a logical OR.
DIO_R
Value
Resource Selected for DIO Pin
0
NONE
1
Reserved
2
T0 (counter0 clock)
3
T1 (counter1 clock)
4
High priority I/O interrupt (INT0 rising)
5
Low priority I/O interrupt (INT1 rising)
6
High priority I/O interrupt (INT0 falling)
7
Low priority I/O interrupt (INT1 falling)
Table 54: Selectable Controls using the DIO_DIR Bits
Additionally, if DIO6 and DIO7 are declared outputs, they can be configured as dedicated pulse outputs (WPULSE = DIO6,
VARPULSE = DIO7) using the I/O RAM registers DIO_PW (0x2008[2]) and DIO_PV (0x2008[3]). In this case, DIO6 and DIO7
are under CE control. DIO4 and DIO5 can be configured to implement the EEPROM Interface by setting the I/O RAM register
DIO_EEX (0x2008[4]).
Physical Memory
Data bus address space is allocated to on-chip memory as shown in Table 55.
Address
(hex)
Memory
Technology
Memory Type
0000-FFFF
Flash Memory
Non-volatile
0000-07FF
1000-13FF
Static RAM
Static RAM
Battery-buffered
Volatile
2000-20FF
Static RAM
Volatile
3000-3FFF
Static RAM
Volatile
Typical Usage
Program and non-volatile
data
MPU data
CE data
Configuration RAM
(I/O RAM)
CE Program code
Wait States
(at 5MHz)
Memory Size
(bytes)
0
64KB
0
5
2KB
1KB
0
256
5
4KB
Table 55: MPU Data Memory Map
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Flash Memory: The 71M6511 includes 64KB of on-chip flash memory. The flash memory is intended to primarily contain MPU
program code. In a typical application, it also contains images of the CE program code, CE coefficients, MPU RAM, and I/O
RAM. On power-up, before enabling the CE, the MPU must copy these images to their respective memory locations.
The I/O RAM bit register FLASH66Z defines the pulse width for accessing flash memory. To minimize supply current draw,
this bit should be set to 1.
Flash erasure is initiated by writing a specific data pattern to specific SFR registers in the proper sequence. These special
pattern/sequence requirements prevent inadvertent erasure of the flash memory.
The mass erase sequence is:
1.
2.
Write 1 to the FLSH_MEEN bit (SFR address 0xB2[1].
Write pattern 0xAA to FLSH_ERASE (SFR address 0x94)
Note: The mass erase cycle can only be initiated when the ICE port is enabled.
The page erase sequence is:
1.
2.
Write the page address to FLSH_PGADR (SFR address 0xB7[7:1]
Write pattern 0x55 to FLSH_ERASE (SFR address 0x94)
Writing to flash memory:
The MPU may write to the flash memory for non-volatile data storage or when implementing a boot-loader. The I/O RAM
register FLSH_PWE (flash program write enable, SFR B2[0]) differentiates 80515 data store instructions (MOVX@DPTR,A)
between Flash and XRAM writes. Before setting FLSH_PWE, all interrupts need to be disabled by setting EAL =1. After the
write operation, FLSH_PWE must be cleared.
The original state of a flash byte is 0xFF (all bits are 1). Overwriting programmed flash cells with a different value usually requires that the cell is erased first. Since cells cannot be erased individually, the page has to be copied to RAM, followed by a
page erase. After this, the page can be updated in RAM and then written back to the flash memory.
Writing to flash locations will affect the corresponding XRAM cells, i.e. 0x2000 to 0x20FF (I/O RAM), 0x0000 to
0x07FF (MPU RAM), plus CE DRAM and CE PRAM. It is critical to maintain the integrity of the cells 0x2000…0x2007
as a minimum (where important system settings are stored) during the flash-write operation. This can be achieved by
excluding the critical addresses from the write operation.
MPU RAM: The 71M6511 includes 2KB of static RAM memory on-chip (XRAM), which are backed-up by the battery plus 256bytes of internal RAM in the MPU core. The 2KB of static RAM are used for data storage during normal MPU operations.
CE DRAM: The CE DRAM is the data memory of the CE. The MPU can read and write the CE DRAM as the primary means of
data communication between the two processors.
CE PRAM: The CE PRAM is the program memory of the CE. The CE PRAM has to be loaded with CE code before the CE
starts operating. CE PRAM cannot be accessed by the MPU when the CE is running.
Oscillator
The oscillator drives a standard 32.768kHz watch crystal (see Figure 9). Crystals of this type are accurate and do not require a
high current oscillator circuit. The oscillator in the TERIDIAN 71M6511 Power Meter IC has been designed specifically to
handle watch crystals and is compatible with their high impedance and limited power handling capability. The oscillator power
dissipation is very low to maximize the lifetime of any battery backup device attached to the VBAT pin.
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71M651X
XIN
crystal
XOUT
Figure 9: Oscillator Circuit
The oscillator should be placed as close as possible to the IC, and vias should be avoided. An external resistor
across the crystal must not be added.
Real-Time Clock (RTC)
The RTC is driven directly by the crystal oscillator. In the absence of the 3.3V supply, the RTC is powered by the external
battery (VBAT pin). The RTC consists of a counter chain and output registers. The counter chain consists of seconds, minutes,
hours, day of week, day of month, month, and year. The RTC is capable of processing leap years. Each counter has its own
output register. Whenever the MPU reads the seconds register, all other output registers are automatically updated. Since the
RTC clock is not coherent to the MPU clock, the MPU must read the seconds register until two consecutive reads are the
same (requires either 2 or 3 reads). At this point, all RTC output registers will have the correct time. Regardless of the MPU
clock speed, RTC reads require one wait state.
The RTC interrupt must be enabled using the I/O RAM register EX_RTC (address 0x2002[1]). RTC time is set by writing to the
I/O RAM registers RTC_SEC, RTC_MIN, through RTC_YR. Each byte written to RTC must be delayed at least 3 CK32 cycles
from any previous byte written to RTC.
Two time correction bits, the I/O RAM registers RTC_DEC_SEC (0x201C[1]) and RTC_INC_SEC (0x201C[0]) are provided to
adjust the RTC time. A pulse on one of these bits causes the time to be decremented or incremented by an additional second
at the next update of the RTC_SEC register. Thus, if the crystal temperature coefficient is known, the MPU firmware can
integrate temperature and correct the RTC time as necessary as discussed in temperature compensation.
LCD Drivers
The 71M6511 contains 15 dedicated LCD segment pins, 5 LCD segment pins that rare shared with the SSI port and/or other
functions, and an additional 12 multi-purpose pins (LCD/DIO) that may be configured as LCD segment drivers (see I/O RAM
register LCD_NUM). Thus, the 71M6511/6511H is capable of driving between 80 to 128 pixels of LCD display with 25% duty
cycle. At seven segments per digit, the LCD can be designed for 11 to 18 digits for display. Since each pixel is addressed
individually, the LCD display can be a combination of alphanumeric digits and enunciator symbols. The information to be
displayed is written into the lower four bits of I/O RAM registers LCD_SEG0 through LCD_SEG37. Bit 0 corresponds to the
segment selected when COM0 pin is active while bit 1 is allocated to COM1.
The LCD driver circuitry is grouped into four common outputs (COM0 to COM3) and up to 32 segment outputs (see Table 56).
Page: 39 of 95
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Dedicated Segment Pins
Shared w/ DIO4-DIO11
Shared w/ DIO14-DIO17
SEG0
SEG1
…
SEG19
SEG24
…
SEG31
SEG34
…
SEG37
COM0
P0
P4
…
P76
P80
…
P108
P112
…
P124
COM1
P1
P5
…
P77
P81
…
P109
P113
...
P125
COM2
P2
P6
…
P78
P82
…
P110
P114
…
P126
COM3
P3
P7
…
P79
P83
…
P111
P115
…
P127
Table 56: Liquid Crystal Display Segment Table (Typical)
Note: P0, P1, … Represent the pixel/segment numbers on the LCD.
A charge pump suitable for driving VLCD is included on-chip. This circuit creates 5V from the 3.3V supply. A contrast DAC is
provided that permits the LCD full-scale voltage to be adjusted between VLCD and 70% of VLCD. The LCD_NUM register
defines the number of dual purpose pins used for LCD segment interface.
LCD Voltage Boost Circuitry
A voltage boost circuit may be used to generate 5V from the 3.3V supply to support low-power 5V devices, such as LCDs.
Figure 10 shows a block diagram of the voltage boost circuitry including the voltage regulators for V2P5 and V2P5NV. When
activated using the I/O RAM register LCD_BSTEN (0x2020[7]), the boost circuitry provides an AC voltage at the VDRV output
pin (see the Applications section for details).
VOLTAGE
BOOST
VDRV
LCD_IBST
LCD_BSTEN
GNDD
V2P5NV
GNDD
V3P3D
VOLT
REG
V3P3D
VBAT
0.1V
GNDD
GNDD
V2P5
V2P5
VLCD
Figure 10: LCD Voltage Boost Circuitry
UART (UART0) and Optical Port (UART1)
The 71M6511/6511H includes an interface to implement an IR or optical port. The pin OPT_TX is designed to directly drive an
external LED for transmitting data on an optical link (low-active). The pin OPT_RX, also low-active, is designed to sense the
input from an external photo detector used as the receiver for the optical link. These two pins are connected to a dedicated
UART port. OPT_TX can be tristated if it is desired to multiplex another I/O pin to the OPT_TX output. The control bit for the
OPT_TX output is the I/O RAM register OPT_TXDIS (0x2008[5]).
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Hardware Reset Mechanisms
Several conditions will cause a hardware reset of the 71M6511/6511H:
•
•
•
•
•
Voltage at the RESETZ pin low
Voltage at the E_RST pin low
Voltage at the V1 pin below reset threshold (VBIAS)
The crystal frequency monitor detected a crystal malfunction
Hardware Watchdog timer
Reset Pin (RESETZ)
When the RESETZ pin is pulled low (or when V1 < VBIAS), all digital activity in the chip stops while analog circuits are still
active. The oscillator and RTC module continue to run. Additionally, all I/O RAM bits are cleared.
Hardware Watchdog Timer
In addition to the basic software watchdog timer included in the 80515 MPU, an independent, robust, fixed-duration, hardware
watchdog timer (WDT) is included in the 71M6511/6511H. This timer will reset the MPU if it is not refreshed periodically, and
can be used to recover the MPU in situations where program control is lost.
The watchdog timer uses the RTC crystal oscillator as its time base and requires a reset under MPU program control at least
every 1.5 seconds. When the WDT overflow occurs, the MPU is momentarily reset as if RESETZ were pulled low for half of a
crystal oscillator cycle. Thus, after 4100 cycles of the CK32 (32768Hz clock), the MPU program will be launched from address
00.
An I/O RAM register status bit, WD_OVF (0x2002[2]), is set when WDT overflow occurs. This bit is powered by the VBAT
pin and can be read by the MPU to determine if the part is initializing after a WDT overflow event or after a power up. After
reading this bit, MPU firmware must clear WD_OVF. The WD_OVF bit is also cleared by the RESETZ pin.
The watchdog timer also includes an oscillator check. If the crystal oscillator stops or slows down, WD_OVF is set and a
system reset will be performed when the crystal oscillator resumes.
There is no internal digital state that deactivates the WDT. For debug purposes, however, the WDT can be disabled by tying
the V1 pin to V3P3 (see Figure 11 and WD Disable Threshold [V1-V3P3A] in the Comparator Section of the Electrical
Specifications). Of course, this also deactivates the power fault detection implemented with V1. Since there is no way in firmware to disable the crystal oscillator or the WDT, it is guaranteed that whatever state the MPU might find itself in, it will be reset
to a known state upon watchdog timer overflow.
In normal operation, the WDT is reset by periodically writing a one to the WDT_RST bit. The watchdog timer is also reset when
WAKE=0 and, during development, when a 0x14 command is received from the ICE port.
Crystal Frequency Monitor
The hardware watchdog timer also includes an oscillator check. If the crystal oscillator stops or slows down, the I/O RAM
register WD_OVF is set and a system reset will be performed when the crystal oscillator resumes.
V1 Pin
The comparator at the V1 pin controls the state of the digital circuitry on the chip. When V1 < VBIAS (or when the RESTZ pin
is pulled low), all digital activity in the chip stops while analog circuits including the oscillator and RTC module are still active.
Additionally, when V1 < VBIAS, all I/O RAM bits are cleared. As long as V1 is greater than VBIAS, the internal 2.5V regulator
will continue to provide power to the digital section.
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V1
V3P3
V3P3-10mV
WDT disabled
V3P3 400mV
Normal
operation,
WDT
enabled
when
(V1 < VBIAS)
the battery is
enabled
VBIAS
Battery or
reset
mode
0V
Figure 11: Voltage Range for V1
I2C Interface (EEPROM)
A dedicated 2-pin serial interface implements an I2C driver that can be used to communicate with external EEPROM devices.
The interface can be multiplexed onto the DIO pins DIO4 (SCK) and DIO5 (SDA) by setting the I/O RAM register DIO_EEX
(0x2008[4]). The MPU communicates with the interface through two SFR registers: EEDATA (0x9E) and EECTRL (0x9F). If
the MPU wishes to write a byte of data to EEPROM, it places the data in EEDATA and then writes the ‘Transmit’ code to
EECTRL. The write to EECTRL initiates the transmit sequence. By observing the BUSY bit in EECTRL the MPU can
determine when the transmit operation is finished (i.e. when the BUSY bit transitions from 1 to 0). INT5 is also asserted when
BUSY falls. The MPU can then check the RX_ACK bit to see if the EEPROM acknowledged the transmission.
A byte is read by writing the ‘Receive’ command to EECTRL and waiting for BUSY to fall. Upon completion, the received data
will appear in EEDATA.
The serial transmit and receive clock is 78kHz during each transmission, and SCL is held in a high state until the next
transmission. The bits in EECTRL are shown in Table 57.
The EEPROM interface can also be operated by controlling the DIO4 and DIO5 pins directly. However, controlling DIO4 and
DIO5 directly is discouraged, because it may tie up the MPU to the point where it may become too busy to process
interrupts.
Note: Clock stretching and multi-master operation is not supported for the I2C interface.
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Status
Bit
Name
Read/
Write
Reset
State
Polarity
Description
7
ERROR
R
0
Positive
1 when an illegal command is received.
6
BUSY
R
0
Positive
1 when serial data bus is busy.
5
RX_ACK
R
1
Negative
0 indicates that the EEPROM sent an ACK bit.
4
TX_ACK
R
1
Negative
0 indicates when an ACK bit has been sent to the EEPROM
CMD
3-0
CMD[3:0]
W
Positive,
see CMD
Table
0
Operation
0
No-op. Applying the no-op command will stop the I2C clock
(SCK, DIO4). Failure to issue the no-op command will keep
the SCK signal toggling.
2
Receive a byte from EEPROM and send ACK.
3
Transmit a byte to EEPROM.
5
Issue a ‘STOP’ sequence.
6
Receive the last byte from EEPROM and do not send ACK.
9
Others
Issue a ‘START’ sequence.
No Operation, set the ERROR bit.
Table 57: EECTRL Status Bits
Internal Clocks and Clock Dividers
All internal clocks are based on the watch crystal frequency (CK32 = 32,768Hz) applied to the XIN and XOUT pins. The PLL
multiplies this frequency by 150 to 4.9152MHz. This frequency is supplied to the ADC, the FIR filter (CKFIR), the clock test
output pin (CKTEST), the CE DRAM and the clock generator. The clock generator provides two clocks, one for the MPU
(CKMPU) and one for the CE (CKCE).
The MPU clock frequency is determined by the I/O RAM register MPU_DIV (0x2004[2:0]) and can be CE*2-MPU_DIV Hz where
MPU_DIV varies from 0 to 7 (MPU_DIV is 0 on power-up). This makes the MPU clock scalable from 4.9152MHz down to
38.4kHz.
The circuit also generates a 2x MPU clock for use by the emulator. This clock is not generated when the I/O RAM register
ECK_DIS (0x2005[5]) is asserted by the MPU.
Battery
The VBAT pin provides an input for an external battery that can be used to support the crystal oscillator, RTC, the WD_OVF bit
and XRAM in the absence of the main power supply. If the battery is not used, the VBAT pin should be connected to V3P3.
Internal Voltages (VBIAS, VBAT, V2P5)
The 71M6511 requires two supply voltages, V3P3A, for the analog section, and V3P3D, for the digital section. Both voltages
can be tied together outside the chip. The internal supply voltage V2P5 is generated by a regulator from the 3.3V supplies.
The battery voltage, VBAT, is required when crystal oscillator, RTC and XRAM are required to keep operating while V3P3D is
removed (battery mode). VBAT, usually supplied by an external battery, powers crystal oscillator, RTC and XRAM (and the
WD_OVF bit).
VBIAS (1.5V) is generated internally and used for the V1 comparator and for the reference of the temperature sensor.
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Test Ports
TMUXOUT Pin: One out of 16 digital or 4 analog signals can be selected to be output on the TMUXOUT pin. The function of
the multiplexer is controlled with the I/O RAM register TMUX (0x2000[3:0]), as shown in Table 58.
TMUX[3:0]
Mode
Function
0
analog
DGND
1
analog
IBIAS
2
analog
PLL_2.5V
3
analog
VBIAS
4
digital
RTM (Real time output from CE)
5
digital
WDTR_EN (Comparator 1 Output AND V1LT3)
6
digital
reserved
7
digital
reserved
8
digital
RXD (from Optical interface)
9
digital
MUX_SYNC
A
digital
CK_10M
B
digital
CK_MPU
C
--
D
digital
E
digital
CE_BUSY
F
digital
XFER_BUSY
reserved for production test
RTCLK
Table 58: TMUX[3:0] Selections
Emulator Port: The emulator port, consisting of the pins E_RST, E_TCLK and E_RXTX provides control of the MPU through
an external in-circuit emulator. The emulator port is compatible with the ADM51 emulators manufactured by Signum Systems.
The signals of the emulator port have weak pull-ups. Adding 1kΩ pull-up resistors on the PCB is recommended.
Real-Time Monitor: The RTM output of the CE is available as one of the digital multiplexer options. RTM data is read from the
CE DRAM locations specified by I/O RAM registers RTM0, RTM1, RTM2, and RTM3 after the rise of MUX_SYNC. The RTM
can be enabled and disabled with I/O RAM register RTM_EN. The RTM output is clocked by CKTEST. Each RTM word is
clocked out in 35 cycles and contains a leading flag bit. Figure 13 in the System Timing Section illustrates the RTM output
format. RTM is low when not in use.
SSI Interface: A high-speed serial interface with handshake capability is available to send a contiguous block of CE data to an
external data logger or DSP. The block of data, configurable as to location and size, is sent starting 1 cycle of 32kHz before
each CE code pass begins. If the block of data is big enough that transmission has not completed when the code pass begins,
it will complete during the CE code pass with no timing impact to the CE or the serial data. In this case, care must be taken
that the transmitted data is not modified unexpectedly by the CE. The SSI interface is enabled by the SSI_EN bit and consists
of SCLK, SSDATA, and SFR as outputs and, optionally, SRDY as input. The interface is compatible with 16bit and 32bit
processors. The operation of each pin is as follows:
SCLK is the serial clock. The clock can be 5MHz or 10MHz, as specified by the SSI_10M bit. The SSI_CKGATE bit controls
whether SCLK runs continuously or is gated off when no SSI activity is occurring. If SCLK is gated, it will begin 3 cycles before
SFR rises and will persist 3 cycles after the last data bit is output.
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The pins used for the SSI are multiplexed with the LCD segment outputs, as shown in Table 59. Thus, the LCD should be
disabled when the SSI is in use.
SSI Signal
LCD Segment
Output Pin
SCLK
SEG3
SSDATA
SEG4
SFR
SEG5
SRDY
SEG6
Table 59: SSI Pin Assignment
SRDY is an optional handshake input that indicates that the DSP or data-logging device is ready to receive data. SRDY must
be high to enable SFR to rise and initiate the transfer of the next field. It is expected that SRDY changes state on the rising
edges of SCLK. If SRDY is not high when the SSI port is ready to transmit the next field, transmission will be delayed until it is.
SRDY is ignored except at the beginning of a field transmission. If SRDY is not enabled (by SSI_RDYEN), the SSI port will
behave as if SRDY is always one.
SSDATA is the serial output data. SSDATA changes on the rising edge of SCLK and outputs the contents of a block of CE
RAM words starting with address SSI_STRT and ending with SSI_END. The words are output MSB first.
The field size is set with the SSI_FSIZE register: 0 entire data block, 1-8 bit fields, 2-16 bit fields, 3-32 bit fields. The polarity of
the SFR pulse can be inverted with SSI_FPOL. If SRDY does not delay it, the first SFR pulse in a frame will rise on the third
SCLK after MUX_SYNC (fourth SCLK if 10MHz). MUX_SYNC can be used to synchronize the fields arriving at the data logger
or DSP.
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Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
FUNCTIONAL DESCRIPTION
Theory of Operation
The energy delivered by a power source into a load can be expressed as:
t
E = ∫ V (t ) I (t )dt
0
Assuming phase angles are constant, the following formulae apply:
P = Real Energy [Wh] = V * A * cos φ* t
Q = Reactive Energy [VARh] = V * A * sin φ * t
S = Apparent Energy [VAh] =
P2 + Q2
For a practical meter, not only voltage and current amplitudes, but also phase angles and harmonic content may change
constantly. Thus, simple RMS measurements are inherently inaccurate. A modern solid-state electricity meter IC such as the
71M6511/6511H functions by emulating the integral operation above, i.e. it processes current and voltage samples through an
ADC at a constant frequency. As long as the ADC resolution is high enough and the sample frequency is beyond the harmonic
range of interest, the current and voltage samples, multiplied with the time period of sampling will yield an accurate quantity for
the momentary energy. Summing up the momentary energy quantities over time will result in accumulated energy.
500
400
V [V], I [A], P [Ws]
300
200
100
0
-100
-200
Current [A]
-300
Voltage [V]
Energy per Interval [Ws]
-400
Accumulated Energy [Ws]
-500
0
5
10
15
time [ms]
20
Figure 12: Voltage. Current, Momentary and Accumulated Energy
Figure 12 shows the shapes of V(t), I(t), the momentary and the accumulated energy, resulting from 50 samples of the voltage
and current signals over a period of 20ms. The application of 240VAC and 100A results in an accumulation of 480Ws over the
20ms period, as indicated by the Accumulated Power curve.
The described sampling method works reliably, even in the presence of dynamic phase shift and harmonic distortion.
Page: 46 of 95
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Single-Phase Energy Meter IC
DATA SHEET
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System Timing Summary
Figure 13 summarizes the timing relationships between the input MUX states, the CE_BUSY signal, and the two serial output
streams. In this example, MUX_DIV = 1 (four mux states) and FIR_LEN = 1 (3 CK32 cycles). Since FIR filter conversions
require two or three CK32 cycles, the duration of each MUX cycle is 1 + 2 * states defined by MUX_DIV if FIR_LEN = 0, and 1
+ 3 * states defined by MUX_DIV if FIR_LEN = 1. Followed by the conversions is a single CK32 cycle.
Each CE program pass begins when MUX_SYNC falls. Depending on the length of the CE program, it may continue running
until the end of the ADC5 conversion. CE opcodes are constructed to ensure that all CE code passes consume exactly the
same number of cycles. The result of each ADC conversion is inserted into the CE DRAM when the conversion is complete.
The CE code is designed to tolerate sudden changes in ADC data. The exact CK count when each ADC value is loaded into
DRAM is shown in Figure 13.
Figure 13 also shows that the two serial data streams, RTM and SSI, begin transmitting at the beginning of MUX_SYNC. RTM,
consisting of 140 CK cycles, will always finish before the next code pass starts. The SSI port begins transmitting at the same
time as RTM, but may significantly overrun the next code pass if a large block of data is required. Neither the CE nor the SSI
port will be affected by this overlap.
ADC, CE and SERIAL TIMING
ADC MUX Frame
ADC TIMING
MUX_DIV Conversions (MUX_DIV=4 is shown)
Settle
CK32
150
MUX_SYNC
MUX STATE
S
0
1
2
3
S
ADC EXECUTION
ADC0
CE TIMING
CE_EXECUTION
0
ADC1
450
900
ADC2
ADC3
1350
CK COUNT = CE_CYCLES + floor((CE_CYCLES + 2) / 5)
1800
MAX CK COUNT
CE_BUSY
XFER_BUSY
INITIATED BY A CE OPCODE AT END OF SUM INTERVAL
RTM and SSI TIMING
140
RTM
SSI
LAST SSI TRANSFER
BEGIN SSI TRANSFER
NOTES:
1. ALL DIMENSIONS ARE 5MHZ CK COUNTS.
2. THE PRECISE FREQUENCY OF CK IS 150*CRYSTAL FREQUENCY = 4.9152MHz.
3. XFER_BUSY OCCURS ONCE EVERY (PRESAMPS * SUM_CYCLES) CODE PASSES.
Figure 13: Timing Relationship between ADC MUX, CE, and Serial Transfers
Figure 14, Figure 15, and Figure 16 show the RTM and SSI timing, respectively.
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Single-Phase Energy Meter IC
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AUGUST 2007
CK32
MUX_SYNC
CKTEST
30
31
0
FLAG
1
30
31
0
FLAG
1
30
31
SIG
N
FLAG
1
LSB
0
SIG
N
31
LSB
30
SIG
N
RTM DATA0 (32 bits)
RTM DATA1 (32 bits)
RTM DATA2 (32 bits)
RTM DATA3 (32 bits)
LSB
FLAG
1
SIG
N
0
LSB
TMUXOUT/RTM
Figure 14: RTM Output Format
If SSI_CKGATE =1
If 16bit fields
If 32bit fields
If SSI_CKGATE =1
SFR (Output)
SRDY (Input)
SCLK (Output)
31
SSDATA (Output)
30
16
15
1
0
31
30
SSI_BEG
16
15
1
0
31
SSI_BEG+1
1
0
SSI_END
MUX_SYNC
Figure 15: SSI Timing, (SSI_FPOL = SSI_RDYPOL = 0)
Next field is delayed while SRDY is low
SFR (Output)
SRDY (Input)
SCLK (Output)
SSDATA (Output)
31
30
29
18
17
16
16
16
16
15
14
13
12
Figure 16: SSI Timing, 16-bit Field Example (External Device Delays SRDY)
SFR is the framing pulse. Although CE words are always 32 bits, the SSI interface will frame the entire data block as a single
field, as multiple 16-bit fields, or as multiple 32-bit fields. The SFR pulse is one SCLK clock cycle wide, changes state on the
rising edge of SCLK and precedes the first bit of each field.
Page: 48 of 95
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Data Flow
The data flow between CE and MPU is shown in Figure 17. In a typical application, the 32-bit compute engine (CE)
sequentially processes the samples from the voltage inputs on pins IA, VA, and IB, performing calculations to measure active
power (Wh), reactive power (VARh), A2h, and V2h for four-quadrant metering. These measurements are then accessed by the
MPU, processed further and output using the peripheral devices available to the MPU.
Pulses
IRQ
CE
Samples
Data
PreProcessor
MPU
PostProcessor
Processed
Metering
Data
I/O RAM (Configuration RAM)
Figure 17: MPU/CE Data Flow
CE/MPU Communication
Figure 18 shows the functional relationship between CE and MPU. The CE is controlled by the MPU via shared registers in the
I/O RAM and by registers in the CE DRAM. The CE outputs two interrupt signals to the MPU: CE_BUSY and XFER_BUSY,
which are connected to the MPU interrupt service inputs as external interrupts. CE_BUSY indicates that the CE is actively
processing data. This signal will occur once every multiplexer cycle. XFER_BUSY indicates that the CE is updating data to the
output region of the CE RAM. This will occur whenever the CE has finished generating a sum by completing an accumulation
interval determined by SUM_CYCLES * PRE_SAMPS samples. Interrupts to the MPU occur on the falling edges of the
XFER_BUSY and CE_BUSY signals.
Figure 19 shows the sequence of events between CE and MPU upon reset or power-up. In a typical application, the sequence
of events is as follows:
1)
2)
3)
4)
5)
Upon power-up, the MPU initializes the hardware, including disabling the CE
The MPU loads the code for the CE into the CE PRAM
The MPU loads CE data into the CE DRAM.
The MPU starts the CE by setting the CE_EN bit in the I/O RAM.
The CE then repetitively executes its code, generating results and storing them in the CE DRAM
It is important to note that the length of the accumulation interval, as determined by NACC, the product of SUM_CYCLES and
PRE_SAMPS is not an exact multiple of 1000ms. For example, if SUM_CYCLES = 60, and PRE_SAMPS = 00 (42), the
resulting accumulation interval is:
τ=
N ACC
60 ⋅ 42
2520
=
=
= 999.75ms
32768 Hz 2520.62 Hz
fS
13
This means that accurate time measurements should be based on the RTC, not the accumulation interval.
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DATA SHEET
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PULSES
W (DIO6)
WSUM
VARSUM
VAR (DIO7)
APULSEW
SERIAL
(UART0/1)
APULSER
EXT_PULSE
DATA
ADC
DISPLAY (memory-mapped
LCD segments)
MPU
EEPROM
(I2C)
SAMPLES
CE_BUSY
CE
Mux Ctrl.
DIO
XFER_BUSY
INTERRUPTS
I/O RAM (CONFIGURATION RAM)
Figure 18: MPU/CE Communication (Functional)
The MPU will wait for the CE to signal that fresh data is ready (the XFER interrupt). It will read the data and perform additional
processing such as energy accumulation.
CE PRAM
FLASH
CE_EN
XFER Interrupt
COMPUTATION
ENGINE
CE DRAM
MPU
Figure 19: MPU/CE Communication (Processing Sequence)
Fault, Reset, Power-Up
Reset Mode: When the RESETZ pin is pulled low or when V1 < VBIAS, all digital activity in the chip stops while analog circuits
are still active. The oscillator and RTC module continue to run. Additionally, all I/O RAM bits are cleared. As long as V1, the
input voltage at the power fault block, is greater than VBIAS, the internal 2.5V regulator will continue to provide power to the
digital section.
Once initiated, the reset mode will persist until the reset timer times out, signified by WAKE rising. This will occur in 4100
cycles of the real time clock after RESETZ goes high, at which time the MPU will begin executing its preboot and boot
sequences from address 00. See the security section for more description of preboot and boot.
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Power-Up: After power-up, the 71M6511/6511H is in reset as long as V1 < VBIAS. As soon as V1 exceeds VBIAS, the reset
timer is started which takes the MPU out of reset after 4100 oscillator cycles (see Figure 20). The MPU then initiates its preboot phase lasting 32 cycles. The supply current will be low but not zero during power-up. It will increase, once V1 exceeds
VBIAS and will increase to the nominal value once the preboot phase starts. The supply current may then be reduced under
firmware control, following the steps specified in Battery Operation and Power Save Modes.
V3P3
V2P5
V1
3.3V
1.5V
0V
POWER
DOWN
PWR
UP
PREBOOT
RESET TIMER
FIRMWARE HAS CONTROL OVER CHIP...
V1 > VBIAS
SUPPLY CURRENT
nominal
1ms
125ms
0mA
Figure 20: Timing Diagram for Voltages, Current and Operation Modes after Power-Up
Battery Operation
When V1 is lower than VBIAS, the external battery will power the following parts of the 71M6511/6511H:
•
•
•
•
RTC
Crystal oscillator circuitry
MPU XRAM
WD_OVF bit
Power Save Modes
In normal mode of operation, running on 3.3V supply, various resources of the 71M6511/6511H may be shut down by the MPU
firmware in order to reduce power consumption while other essential resources such as UARTs may remain active. Table 60
outlines these resources and their typical current consumption (based on initial condition MPU_DIV = 0).
Power Saving Measure
Disable the CE
Software Control
Typical
Savings
CE_EN = 0
0.16mA
ADC_DIS = 1
1.8mA
Disable clock test output CKTEST
CKOUTDIS = 1
0.6mA
Disable emulator clock
ECK_DIS = 1 *)
0.1mA
FLASH66Z =1
0.04mA
LCD_BSTEN = 0
0.9mA
RTM_EN = 0
0.01mA
Disable the ADC
Set flash read pulse timing to 33 ns
Disable the LCD voltage boost circuitry
Disable RTM outputs
Increase the clock divider for the MPU
MPU_DIV = X
0.4mA/MHz
*) This bit is to be used with caution! Inadvertently setting this bit will inhibit access to the part with the ICE interface and thus
preclude flash erase and programming operations.
Table 60: Power Saving Measures
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Temperature Compensation
Internal Compensation: The internal voltage reference is calibrated during device manufacture. Trim data is stored in on-chip
fuses.
For the 71M6511, the temperature coefficients TC1 and TC2 are given as constants that represent typical component
behavior.
For the 71M6511H, the temperature characteristics of the chip are measured during production and then stored in the fuse
registers TRIMBGA, TRIMBGB and TRIMM[2:0]. TC1 and TC2 can be derived from the fuses by using the relations given in
the Electrical Specifications section. TC1 and TC2 can be further processed to generate the coefficients PPMC and PPMC2.
TRIMM[2:0], TRIMBGA and TRIMBGB are read by first writing either 4, 5 or 6 to TRIMSEL (0x20FD) and then reading the
value of TRIM (0x20FF).
When the EXT_TEMP register in CE DRAM (address 0x38) is set to 0, the CE automatically compensates for temperature
errors by controlling the GAIN_ADJ register (address 0x2E) based on the PPMC, PPMC2, and TEMP_X register values. In the
case of internal compensation, GAIN_ADJ is an output of the CE.
External Compensation: Rather than internally compensating for the temperature variation, the bandgap temperature is
provided to the embedded MPU, which then may digitally compensate the power outputs. This permits a system-wide
temperature correction over the entire system rather than local to the chip. The incorporated thermal coefficients may include
the current sensors, the voltage sensors, and other influences. Since the band gap is chopper stabilized via the CHOP_EN
bits, the most significant long-term drift mechanism in the voltage reference is removed.
When the EXT_TEMP register in CE DRAM is set to 15, the CE ignores the PPMC, PPMC2, and TEMP_X register values and
applies the gain supplied by the MPU in GAIN_ADJ. External compensation enables the MPU to control the CE gain based on
any variable, and when EXT_TEMP = 15, GAIN_ADJ is an input to the CE.
Chopping Circuitry
As explained in the hardware section, the bits of the I/O RAM register CHOP_ENA[1:0] have to be toggled in between
multiplexer cycles to achieve the desired elimination of DC offset.
The amplifier within the reference is auto-zeroed by means of an internal signal that is controlled by the CHOP_EN bits. When
this signal is HIGH, the connection of the amplifier inputs is reversed. This preserves the overall polarity of the amplifier gain
but inverts the input offset. By alternately reversing the connection, the offset of the amplifier is averaged to zero. The two bits
of the CHOP_EN register have the function specified in Table 61.
CHOP_EN[1]
CHOP_EN[0]
Function
0
0
Toggle chop signal
0
1
Reference connection positive
1
0
Reference connection reversed
1
1
Toggle chop signal
Table 61: CHOP_EN Bits
For automatic chopping, the CHOP_EN bits are set to either 00 or 11. In this mode, the polarity of the signals feeding the
reference amplifier will be automatically toggled for each multiplexer cycle as shown in Figure 21. With an even number of
multiplexer cycles in each accumulation interval, the number of cycles with positive reference connection will equal the number
of cycles with reversed connection, and the offset for each sampled signal will be averaged to zero. This sequence is
acceptable when only the primary signals (meter voltage, meter current) are of interest.
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Accumulation Interval m
MUX
cycle 1
MUX
cycle 2
MUX
cycle 3
Accumulation Interval m+2
Accumulation Interval m+1
MUX
cycle n
MUX
cycle 1
Reversed
Positive
MUX
cycle n
MUX
cycle 1
Reversed
Positive
Chop Polarity
Reversed
Positive
Positive
Reversed
Positive
Reversed
Positive
CE_BUSY interrupt
(falling edge)
XFER_BUSY interrupt
(falling edge)
Figure 21: Chop Polarity w/ Automatic Chopping
If temperature compensation or accurate reading of the die temperature is required, alternate multiplexer cycles have to be
inserted in between the regular cycles. This is done under MPU firmware control by asserting the MUX_ALT bit whenever
necessary. Since die temperature usually changes very slowly, alternate multiplexer cycles have to be inserted very
infrequently. Usually, an alternate multiplexer cycle is inserted once for every accumulation period, i.e. after each XFER_BUSY
interrupt. This sequence is shown in Figure 22.
Accumulation Interval m
MUX
alt. MUX MUX
cycle 2 cycle 3
cycle
Accumulation Interval m+1
MUX alt. MUX
cycle n cycle
Accumulation Interval m+2
MUX alt. MUX
cycle n cycle
Chop Polarity
Positive
RePositive
versed
RePositive
versed
Re- Positive
versed
Reversed
Positive
Reversed
Positive
CE_BUSY interrupt
XFER_BUSY interrupt
MUX_ALT
Figure 22: Sequence with Alternate Multiplexer Cycles
This sequence has the disadvantage that the alternate multiplexer cycle is always operated with positive connection.
Consequently, DC offset will appear on the temperature measurement, which will decrease the accuracy of this measurement
and thus cause temperature reading and compensation to be less accurate.
The sequence shown in Figure 23 uses the CHOP_EN bits to control the chopper polarity after each XFER_BUSY interrupt.
CHOP_EN is controlled to alternate between 10 (positive) and 01 (reversed) for the first multiplexer cycle following each
Page: 53 of 95
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XFER_BUSY interrupt. After these first two cycles, CHOP_EN returns to 11 (automatic toggle). The value of CHOP_EN, when
set after the XFER_BUSY interrupt, is in force for the entire following multiplexer cycle.
When using this sequence, the alternate multiplexer cycle is toggled between positive and reversed connection resulting in
accurate temperature measurement.
An example for proper application of the CHOP_EN bits can be found in the Demo Code shipped with the 6511 and 6511
Demo Kits. Firmware implementations should closely follow this example.
Accumulation Interval m
alt. MUX MUX
cycle 2
cycle
MUX
cycle 3
Accumulation Interval m+1
Accumulation Interval m+2
MUX
cycle n
alt. MUX MUX
cycle 2
cycle
MUX
cycle 3
MUX
cycle n
alt. MUX MUX
cycle 2
cycle
MUX
cycle 3
MUX
cycle n
Positive
reversed
Positive
reversed
Positive Positive
reversed
Positive
Chop Polarity
rePositive Positive versed
reversed
CE_BUSY interrupt
XFER_BUSY interrupt
MUX_ALT
CHOP_EN
01
11
(11)
(11)
(11)
10
11
(11)
(11)
(11)
01
11
(11)
(11)
(11)
Figure 23: Sequence with Alternate Multiplexer Cycles and Controlled Chopping
Internal/External Pulse Generation and Pulse Counting
The CE is the source for pulses. It can generate pulses directly based on the voltage and current inputs and the configured
pulse generation parameters. This is called “internal pulse generation”, and applies when the CE RAM register EXT_PULSE
(address 0x37) equals 0. Alternatively, the CE can be configured to generate pulses based on registers that are controlled by
the MPU (“external pulse generation”), i.e. when the register EXT_PULSE equals 15. In the case of external pulse generation,
the MPU writes values to the CE registers APULSEW (0x26) and APULSER (0x27).
The pulse rate, usually inversely expressed as “Kh” (and measured in Wh per pulse), is determined by the CE RAM registers
WRATE, PULSE_SLOW, PULSE_FAST, In_8, as well as by the sensor scaling VMAX and IMAX per the equation:
Kh =
VMAX ⋅ IMAX ⋅ 47.1132
[Wh / pulse]
In _ 8 ⋅ WRATE ⋅ N ACC ⋅ X
where
In_8 is the gain factor (1 or 8) controlled by the CE variable In_SHUNT,
X is the pulse gain factor controlled by the CE variables PULSE_SLOW and PULSE_FAST
NACC is the accumulation count (PRE_SAMPS * SUM_CYCLES)
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Program Security
When enabled, the security feature limits the ICE to global flash erase operations only. All other ICE operations are blocked.
This guarantees the security of the user’s MPU and CE program code. Security is enabled by MPU code that is executed in a
32 cycle preboot interval before the primary boot sequence begins. Once security is enabled, the only way to disable it is to
perform a global erase of the flash memory, followed by a chip reset. Global flash erase also clears the CE PRAM.
The first 32 cycles of the MPU boot code are called the preboot phase because during this phase the ICE is inhibited. A readonly status bit, PREBOOT (SFR 0xB2[7]), identifies these cycles to the MPU. Upon completion of the preboot sequence, the
ICE can be enabled and is permitted to take control of the MPU.
SECURE (SFR 0xB2[6]), the security enable bit, is reset whenever the MPU is reset. Hardware associated with the bit permits
only ones to be written to it. Thus, preboot code may set SECURE to enable the security feature but may not reset it. Once
SECURE is set, the preboot code is protected and no external read of program code is possible.
Specifically, when SECURE is set:
•
•
•
The ICE is limited to bulk flash erase only.
Page zero of flash memory, the preferred location for the user’s preboot code, may not be page-erased by either MPU or
ICE. Page zero may only be erased with global flash erase. Note that global flash erase erases CE program RAM whether
SECURE is set or not.
Writes to page zero, whether by MPU or ICE, are inhibited.
The SECURE bit is to be used with caution! Inadvertently setting this bit will inhibit access to the part via the ICE
interface, if no mechanism for actively resetting the part between reset and erase operations is provided (see ICE
Interface description).
Additionally, by setting the I/O RAM register ECK_DIS to 1, the emulator clock is disabled, inhibiting access to the program
with the emulator. See the cautionary note in the I/O RAM Register description!
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FIRMWARE INTERFACE
I/O RAM MAP – In Numerical Order
‘Not Used’ bits are blacked out and contain no memory and are read by the MPU as zero. RESERVED bits are in use and
should not be changed.
Name
CE0
CE1
CE2
COMP0
CONFIG0
CONFIG1
VERSION
Addr
Bit 7
Bit 6
Bit 5
Bit 4
Configuration:
Bit 3
Bit 2
Bit 1
EQU[2:0]
2000
PRE_SAMPS[1:0]
2001
MUX_DIV[1:0]
2002
2003
2004 VREF_CAL
2005 RESERVED
2006
TMUX[3:0]
SUM_CYCLES[5:0]
CHOP_EN[1:0]
RTM_EN
WD_OVF
EX_RTC
RESERVED
RESERVED
RESERVED CKOUT_DIS VREF_DIS
MPU_DIV
ECK_DIS
FIR_LEN
ADC_DIS
MUX_ALT
FLASH66Z
VERSION[7:0]
DIO0
DIO1
DIO2
DIO3
DIO4
DIO5
DIO6
2008
2009
200A
200B
200C
200D
200E
OPT_TXDIS
RESERVED
RESERVED
DIO_R5[2:0]
DIO_R7[2:0]
DIO_R9[2:0]
DIO_R11[2:0]
RTC0
RTC1
RTC2
RTC3
RTC4
RTC5
RTC6
RTC7
2015
2016
2017
2018
2019
201A
201B
201C
Bit 0
CE_EN
EX_XFR
COMP_STAT[0]
MUX_E
Digital I/O:
DIO_EEX
DIO_PW
DIO_PV
RESERVED
RESERVED
DIO_R4[2:0]
DIO_R6[2:0]
DIO_R8[2:0]
DIO_R10[2:0]
Real Time Clock:
RTC_SEC[5:0]
RTC_MIN[5:0]
RTC_HR[4:0]
RTC_DAY[2:0]
RTC_DATE[4:0]
RTC_MO[3:0]
RTC_YR[7:0]
RTC_DEC_SEC RTC_INC_SEC
LCD Display Interface:
LCDX
LCDY
LCDZ
LCD0
LCD1
…
LCD19
LCD20
…
LCD23
LCD24
…
LCD31
LCD32
LCD33
LCD34
LCD35
LCD36
2020 LCD_BSTEN
2021
2022
2030
2031
…
2043
2044
…
2047
2048
…
204F
2050
2051
2052
2053
2054
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LCD_EN
LCD_NUM[4:0]
LCD_MODE[2:0]
LCD_CLK[1:0]
LCD_FS[4:0]
LCD_SEG0[3:0]
LCD_SEG1[3:0]
…
LCD_SEG19[3:0]
RESERVED
…
RESERVED
LCD_SEG24[3:0]
…
LCD_SEG31[3:0]
LCD_SEG32[3:0]
LCD_SEG33[3:0]
LCD_SEG34[3:0]
LCD_SEG35[3:0]
LCD_SEG36[3:0]
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
LCD37
LCD38
LCD39
LCD40
LCD41
2055
2056
2057
2058
2059
RTM0
RTM1
RTM2
RTM3
2060
2061
2062
2063
LCD_SEG37[3:0]
RESERVED
RESERVED
RESERVED
RESERVED
RTM Probes:
RTM0[7:0]
RTM1[7:0]
RTM2[7:0]
RTM3[7:0]
Synchronous Serial Interface:
SSI
2070
S S I _ B E G 2071
SSI_END 2072
SSI_EN
SSI_10M
SSI_CKGATE
SSI_FSIZE[1:0]
SSI_BEG[7:0]
SSI_END[7:0]
SSI_FPOL
SSI_RDYEN
SSI_RDYPOL
Fuse Selection Registers:
TRIMSEL 20FD
TRIM
20FF
TRIMSEL[7:0]
TRIM[7:0]
SFR MAP (SFRs Specific to TERIDIAN 80515) – In Numerical Order
‘Not Used’ bits are blacked out and contain no memory and are read by the MPU as zero. RESERVED bits are in use and
should not be changed. This table lists only the SFR registers that are not generic 8051 SFR registers.
Name
SFR
Addr
P0
DIR0
P1
DIR1
P2
DIR2
80
A2
90
91
A0
A1
DIO_0[7:4] (Port 0)
DIO_DIR0[7:4]
DIO_1[7:6] (Port 1)
DIO_DIR1[7:6]
INTBITS
WDI
F8
E8
INT6
ERASE
FLSHCTL
PGADR
94
B2
B7
EEDATA
EECTRL
9E
9F
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Digital I/O:
RESERVED
1111
RESERVED
1111
DIO_1[3:0] (Port 1)
DIO_DIR1[3:0]
DIO_2[1:0] (Port 2)
DIO_DIR2[1:0]
Interrupts and WD Timer:
INT5
INT4
INT3
INT2
WD_RST
INT1
IE_RTC
INT0
IE_XFER
FLSH_MEEN
FLSH_PWE
Flash:
FLSH_ERASE[7:0]
PREBOOT
SECURE
FLSH_PGADR[6:0]
Serial EEPROM:
Page: 57 of 95
EEDATA[7:0]
EECTRL[7:0]
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
I/O RAM (Configuration RAM) – Alphabetical Order
Many functions of the chip can be controlled via the I/O RAM (Configuration RAM). The CE will also take some of its parameters from the I/O RAM.
Bits with a W (write) direction are written by the MPU into I/O RAM. Typically, they are initially stored in flash memory and
copied to the I/O RAM by the MPU. Some of the more frequently programmed bits are mapped to the MPU SFR memory
space. The remaining bits are mapped to 2xxx. Bits with R (read) direction can only be read by the MPU. On power up, all
bits are cleared to zero unless otherwise stated. Generic SFR registers are not listed.
Name
Location
[Bit(s)]
Dir
Description
ADC_DIS
2005[3]
R/W
Disables ADC and removes bias current
CE_EN
2000[4]
R/W
CE enable.
CHOP_EN[1:0]
2002[5:4]
R/W
Chop enable for the reference band gap circuit.
00: enabled 01: disabled 10: disabled 11: enabled
RESERVED
2004[5]
R/W
Must be 0.
CKOUT_DIS
2004[4]
R/W
CKOUT Disable. When zero, CKTEST is an active output.
RESERVED
2003[4:3]
R/W
Must be 0.
RESERVED
2003[2:0]
R
Reserved
DIO_R4[2:0]
DIO_R5[2:0]
DIO_R6[2:0]
DIO_R7[2:0]
DIO_R8[2:0]
DIO_R9[2:0]
DIO_R10[2:0]
DIO_R11[2:0]
200B[2:0]
200B[6:4]
200C[2:0]
200C[6:4]
200D[2:0]
200D[6:4]
200E[2:0]
200E[6:4]
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Connects dedicated I/O pins 4 to 11 to selectable internal resources. If
more than one input is connected to the same resource, the ‘Multiple’
column below specifies how they are combined. See Software User’s
Guide for details).
DIO_DIR0[7:4]
SFR A2
R/W
Programs the direction of DIO pins 7 through 4. 1 indicates output.
Ignored if the pin is not configured as I/O. See DIO_PV and DIO_PW
for special option for DIO6 and DIO7 outputs. See DIO_EEX for
special option for DIO4 and DIO5.
Note: Bit 0, Bit 1, Bit 2 and Bit 3 must be set to 1.
Page: 58 of 95
DIO_GP
0
1
2
3
4
5
6
7
Resource
NONE
Reserved
T0 (counter0 clock)
T1 (counter1 clock)
High priority I/O interrupt (int0 rising)
Low priority I/O interrupt (int1 rising)
High priority I/O interrupt (int0 falling)
Low priority I/O interrupt (int1 falling)
© 2005-2007 TERIDIAN Semiconductor Corporation
Multiple
-OR
OR
OR
OR
OR
OR
OR
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
DIO_DIR1[7:6]
DIO_DIR1[3:0]
SFR91
R/W
Programs the direction of DIO pins 15, 14 and 11 through 8. 1
indicates output. Ignored if the pin is not configured as I/O.
Note: Bit 4 and Bit 5 must be set to 1.
DIO_DIR2[1:0]
SFRA1[5:0]
R/W
Programs the direction of DIO pins 17 and 16. 1 indicates output.
Ignored if the pin is not configured as I/O.
Note: Bit 2, Bit 3, Bit 4 and Bit 5 must be set to 1.
DIO_0[7:4]
SFR80
R/W
Port 0
The value on the DIO pins. Pins configured as LCD will read
zero. When written, changes data on pins configured as
outputs. Pins configured as LCD or input will ignore writes.
DIO_1[7:6],
DIO_1[3:0]
SFR90
SFR90
R/W
R/W
Port 1
Port 1
DIO_2[1:0]
SFRA0[1:0]
R/W
Port 2
DIO_EEX
2008[4]
R/W
When set, converts DIO4 and DIO5 to interface with external
EEPROM. DIO4 becomes SCK and DIO5 becomes bi-directional SDA.
LCD_NUM must be less than 18.
DIO_PV
2008[2]
R/W
Causes VARPULSE to be output on DIO7, if DIO7 is configured as
output. LCD_NUM must be less than 15.
DIO_PW
2008[3]
R/W
Causes WPULSE to be output on DIO6, if DIO6 is configured as
output. LCD_NUM must be less than 17.
EEDATA[7:0]
SFR 9E
R/W
Serial EEPROM interface data
EECTRL[7:0]
SFR 9F
R/W
Serial EEPROM interface control
ECK_DIS
2005[5]
R/W
Emulator clock disable. When one, the emulator clock is disabled.
This bit is to be used with caution! Inadvertently setting
this bit will inhibit access to the part with the ICE
interface and thus preclude flash erase and programming
operations. If ECK_DIS is set, it should be done at least 1000ms after
power-up to give emulators and programming devices enough time to
complete an erase operation.
EQU[2:0]
2000[7:5]
R/W
Specifies the power equation to the CE.
EX_XFR
2002[0]
R/W
EX_RTC
2002[1]
Interrupt enable bits. These bits enable the XFER_BUSY and the
RTC_1SEC interrupts to the MPU. Note that if either interrupt is to be
enabled, EX6 in the 80515 must also be set.
FIR_LEN
2005[4]
R/W
The length of the ADC decimation FIR filter.
1: 22 ADC bits/3 CK32 cycles (384 CKFIR cycles),
0: 21 ADC bits/2 CK32 cycles (288 CKFIR cycles)
FLASH66Z
Page: 59 of 95
2005[1]
R/W
Should be set to 1 to minimize supply current.
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
FLSH_ERASE
SFR 94
W
Flash Erase Initiate
FLSH_ERASE is used to initiate either the Flash Mass Erase cycle or
the Flash Page Erase cycle. Specific patterns are expected for
FLSH_ERASE in order to initiate the appropriate Erase cycle.
(default = 0x00).
0x55 – Initiate Flash Page Erase cycle. Must be proceeded by a write
to FLSH_PGADR @ SFR 0xB7.
0xAA – Initiate Flash Mass Erase cycle. Must be proceeded by a write
to FLSH_MEEN @ SFR 0xB2 and the debug (CC) port must
be enabled.
Any other pattern written to FLSH_ERASE will have no effect.
FLSH_MEEN
SFR B2[1]
W
Mass Erase Enable
0 – Mass Erase disabled (default).
1 – Mass Erase enabled.
Must be re-written for each new Mass Erase cycle.
FLSH_PGADR
SFR B7[7:1]
W
Flash Page Erase Address
FLSH_PGADR[6:0] – Flash Page Address (page 0 thru 127) that will
be erased during the Page Erase cycle. (default = 0x00).
Must be re-written for each new Page Erase cycle.
FLSH_PWE
SFR B2[0]
R/W
Program Write Enable
0 – MOVX commands refer to XRAM Space, normal operation
(default).
1 – MOVX @DPTR,A moves A to Program Space (Flash) @ DPTR.
This bit is automatically reset after each byte written to flash. Writes to
this bit are inhibited when interrupts are enabled.
IE_XFER
SFR E8[0]
IE_RTC
SFR E8[1]
R/W
Interrupt flags. These flags are part of the WDI SFR register and monitor the XFER_BUSY interrupt and the RTC_1SEC interrupt. The
flags are set by hardware and must be cleared by the interrupt handler.
See also WD_RST.
INTBITS
SFR F8[6:0]
R
Interrupt inputs. The MPU may read these bits to see the input to
external interrupts INT0, INT1, up to INT6. These bits do not have any
memory and are primarily intended for debug use.
LCD_BSTEN
2020[7]
R/W
Enables the LCD voltage boost circuit.
LCD_CLK[1:0]
2021[1:0]
R/W
Sets the LCD clock frequency for COM/SEG pins (not the frame rate.
Note: fw = CKFIR/128
00: fw/29, 01: fw/28, 10: fw/27, 11: fw/26
LCD_EN
2021[5]
R/W
Enables the LCD display. When disabled, VLC2, VLC1, and VLC0 are
ground as are the COM and SEG outputs.
LCD_FS[4:0]
2022[4:0]
R/W
Controls the LCD full scale voltage, VLC2:
VLC 2 = VLCD ⋅ (0.7 + 0.3
Page: 60 of 95
LCD _ FS
)
31
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
LCD_MODE[2:0]
2021[4:2]
R/W
The LCD bias mode.
000:
001:
010:
011:
100:
LCD_NUM[4:0]
2020[4:0]
R/W
4 states, 1/3 bias
3 states, 1/3 bias
2 states, ½ bias
3 states, ½ bias
static display
Controls the number of dual-purpose LCD/DIO pins to be configured
as LCD. LCD_NUM will be between 0 and 18. The first dual-purpose
pin to be allocated as LCD is SEG37/DIO17. The table below lists
which SEG and DIO functions are selected for each LCD_NUM value.
LCD_NUM
1-4
LCD_SEG0[3:0]LCD_SEG19[3:0],
2030[3:0]2043[3:0],
LCD_SEG24[3:0]LCD_SEG31[3:0],
2048[3:0]204f[3:0],
LCD_SEG34[3:0]LCD_SEG37[3:0],
2052[3:0]2055[3:0]
MPU_DIV[2:0]
2004[2:0]
SEG
DIO
None
DIO4-11, DIO14-17
5
SEG37
DIO4-11, DIO14-16
6
SEG36-37
DIO4-11, DIO14-15
7
SEG35-37
DIO4-11, DIO14
8-10
SEG34-37
DIO4-11
11
SEG34-37, SEG31
DIO4-10
12
SEG34-37, SEG30-31
DIO4-9
13
SEG34-37, SEG29-31
DIO4-8
14
SEG34-37, SEG28-31
DIO4-7
15
SEG34-37, SEG27-31
DIO4-6
16
SEG34-37, SEG26-31
DIO4-5
17
SEG34-37, SEG25-31
DIO4
18
SEG34-37, SEG24-31
None
R/W
LCD Segment Data. Each word contains information for from 1 to 4
time divisions of each segment. In each word, bit 0 corresponds to
COM0, on up to bit 3 for COM3.
R/W
The MPU clock divider (from CKCE). These bits may be programmed
by the MPU without risk of losing control.
000 - CKCE, 001 - CKCE/2, …, 111 - CKCE/27
MPU_DIV is 000 on power-up.
MUX_ALT
2005[2]
R/W
The MPU asserts this bit when it wishes the MUX to perform ADC
conversions on an alternate set of inputs.
MUX_DIV[1:0]
2002[7:6]
R/W
The number of states in the input multiplexer.
MUX_E
2005[0]
R/W
MUX_SYNC enable. When high, converts SEG7 into a MUX_SYNC
output.
OPT_TXDIS
2008[5]
R/W
Tristates the OPT_TX output.
00 - 6 states
Page: 61 of 95
01 - 4 states
10 - 3 states
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11 - 2 states
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71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
PREBOOT
SFR B2[7]
R
PRE_SAMPS[1:0]
2001[7:6]
R/W
Indicates that the preboot sequence is active.
Together w/ SUM_CYCLES, this value determines the number of
samples in one sum cycle between XFER interrupts for the CE.
Number of samples = PRE_SAMPS*SUM_CYCLES.
00-42, 01-50, 10-84, 11-100
RTC_SEC[5:0]
RTC_MINI[5:0]
RTC_HR[4:0]
RTC_DAY[2:0]
RTC_DATE[4:0]
RTC_MO[3:0]
RTC_YR[7:0]
2015
2016
2017
2018
2019
201A
201B
R/W
The RTC interface. These are the ‘year’, ‘month’, ‘day’, ‘hour’, ‘minute’
and ‘second’ parameters for the RTC. The RTC is set by writing to
these registers. Year 00 is defined as a leap year.
SEC 00 to 59
MIN 00 to 59
HR
00 to 23 (00=Midnight)
DAY 01 to 07 (01=Sunday)
DATE 01 to 31
MO 01 to 12
YR
00 to 256
RTC_DEC_SEC
201C[1]
RTC_INC_SEC
201C[0]
W
RTC time correction bits. Only one bit may be pulsed at a time. When
pulsed, causes the RTC time value to be incremented (or
decremented) by an additional second the next time the RTC_SEC
register is clocked. The pulse width may be any value. If an additional
correction is desired, the MPU must wait 2 seconds before pulsing one
of the bits again.
RTM_EN
2002[3]
R/W
Real Time Monitor enable. When ‘0’, the RTM output is low. This bit
enables the two wire version of RTM
RTM0[7:0]
RTM1[7:0]
RTM2[7:0]
RTM3[7:0]
2060
2061
2062
2063
R/W
R/W
R/W
R/W
Four RTM probes. Before each CE code pass, the values of these
registers are serially output on the RTM pin. The RTM registers are
ignored when RTM_EN=0.
SECURE
SFR B2[6]
R/W
Enables security provisions that prevent external reading of flash
memory and CE program RAM. This bit is reset on chip reset and may
only be set. Attempts to write zero are ignored.
SSI_EN
2070[7]
R/W
Enables the Synchronous Serial Interface (SSI) on SEG3, SEG4, and
SEG5 pins. If SSI_RDYEN is set, SEG6 is enabled also. The pins take
on the new functions SCLK, SSDATA, SFR, and SRDY, respectively.
When SSI_EN is high and LCD_EN is low, these pins are converted to
the SSI function, regardless of LCDEN and LCD_NUM. For proper
LCD operation, SSI_EN must not be high when LCD_EN is high.
SSI_10M
2070[6]
R/W
SSI clock speed: 0: 5MHz, 1: 10MHz
SSI_CKGATE
2070[5]
R/W
SSI gated clock enable. When low, the SCLK is continuous. When
high, the clock is held low when data is not being transferred.
SSI_FSIZE[1:0]
2070[4:3]
R/W
SSI frame pulse format:
0: once at beginning of SSI sequence (whole block of data),
1: every 8 bits, 2: every 16 bits, 3: every 32 bits.
SSI_FPOL
2070[2]
R/W
SFR pulse polarity: 0: positive, 1: negative
SSI_RDYEN
2070[1]
R/W
SRDY enable. If SSI_RDYEN and SSI_EN are high, the SEG6 pin is
configured as SRDY. Otherwise, it is an LCD driver.
SSI_RDYPOL
2070[0]
R/W
SRDY polarity: 0: positive, 1: negative
Page: 62 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
SSI_BEG[7:0]
2071[7:0]
SSI_END[7:0]
2072[7:0]
SUM_CYCLES
[5:0]
2001[5:0]
R/W
TMUX[3:0]
2000[3:0]
R/W
Selects one of 16 inputs for TMUXOUT.
0 – DGND (analog)
1 – IBIAS (analog)
2 – PLL_2.5V (analog)
3 – VBIAS (analog)
4 – RTM (Real time output from CE)
5 – WDTR_EN (Comparator 1 Output AND V1LT3)
6 – reserved
7 – reserved
8 – RXD (from Optical interface)
9 – MUX_SYNC (from MUX_CTRL)
A – CK_10M
B – CK_MPU
C – reserved for production test
D – RTCLK
E – CE_BUSY
F – XFER_BUSY
RESERVED
2005[7]
R/W
Must be zero.
TRIMSEL
20FD
W
Selects the temperature trim fuse to be read with the TRIM register
(TRIMM[2:0]: 4, TRIMBGA: 5, TRIMBGB: 6)
TRIM
20FF
R
Contains TRIMBGA, TRIMBGB, or TRIMM[2:0] depending on the
value written to TRIMSEL. If TRIMBGB = 0 then the IC is a 6511 else
the IC is a 6511H.
VERSION[7:0]
2006
R
The silicon revision number. This data sheet does not apply to
revisions < 000 0100.
VREF_CAL
2004[7]
R/W
Brings VREF out to the VREF pin. This feature is disabled when
VREF_DIS=1.
VREF_DIS
2004[3]
R/W
Disables the internal voltage reference.
WD_RST
SFR E8[7]
WD_OVF
2002[2]
Page: 63 of 95
R/W
The beginning and ending address of the transfer region of the CE
data memory. If the SSI is enabled, a block of words starting with
SSI_BEG and ending with SSI_END will be sent. SSI_END must be
larger than SSI_BEG. The maximum number of output words is limited
by the number of SSI clocks in a CE code pass—see FIR_LEN,
MUX_DIV, and SSI_10M.
Together w/ PRE_SAMPS, this value determines (for the CE) the
number of samples in one sum cycle between XFER interrupts.
Number of samples = PRE_SAMPS*SUM_CYCLES.
W
Resets the WD timer. The WDT is reset when a 1 is written to this bit.
Only byte operations on the whole WDI register should be used.
R/W
The WD overflow status bit. This bit is set when the WD timer
overflows. It is powered by the VBAT pin and at boot-up will indicate if
the part is recovering from a WD overflow or a power fault. This bit
should be cleared by the MPU on boot-up. It is also automatically
cleared when RESETZ is low.
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
CE Program and Environment
CE Program
The CE program is supplied by TERIDIAN as a data image that can be merged with the MPU operational code for meter
applications. Typically, the CE program covers most applications and does not need to be modified. The description in this
section applies to CE code revision CE11B05.
Formats
All CE words are 4 bytes. Unless specified otherwise, they are in 32-bit two’s complement (-1 = 0xFFFFFFFF). ‘Calibration’
parameters are defined in flash memory (or external EEPROM) and must be copied to CE memory by the MPU before
enabling the CE. ‘Internal’ variables are used in internal CE calculations. ‘Input’ variables allow the MPU to control the behavior
of the CE code. ‘Output’ variables are outputs of the CE calculations. The corresponding MPU address for the most significant
byte is given by 0x1000 + 4 x CE_address and 0x1003 + 4 x CE_address for the least significant byte.
Constants
Constants used in the CE Data Memory tables are:
Sampling frequency: FS = 32768Hz/13 = 2520.62Hz (MUX_DIV = 1) or 32786/10 = 3276.8Hz (MUX_DIV = 2)
F0 is the fundamental signal frequency, typically 50 or 60Hz.
IMAX is the external rms current corresponding to 250mV peak at the inputs IA or IB.
VMAX is the external rms voltage corresponding to 250mV peak at the input VA.
NACC, the accumulation count for energy measurements is PRE_SAMPS*SUM_CYCLES. This value resides in
SUM_PRE (CE address 36).
Accumulation count time for energy measurements is PRE_SAMPS*SUM_CYCLES/FS.
In_8 is a gain constant of current channel n. Its value is 8 or 1 and is controlled by In_SHUNT.
X is a gain constant of the pulse generators. Its value is determined by PULSE_FAST and PULSE_SLOW.
-9
Voltage LSB = VMAX * 3.3243*10 V (peak).
The system constants IMAX and VMAX are used by the MPU to convert internal digital quantities (as used by the CE) to
external, i.e. metering quantities. Their values are determined by the scaling of the voltage and current sensors used in an
actual meter. The LSB values used in this document relate digital quantities at the CE or MPU interface to external meter input
quantities. For example, if a SAG threshold of 80V peak is desired at the meter input, the digital value that should be programmed into SAG_THR would be 80V/SAG_THRLSB, where SAG_THRLSB is the LSB value in the description of SAG_THR.
The parameters EQU, CE_EN, PRE_SAMPS, and SUM_CYCLES are essential to the function of the CE and are stored in I/O
RAM (see I/O RAM section).
Page: 64 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
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Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Environment
Before starting the CE using the CE_EN bit, the MPU has to establish the proper environment for the CE by implementing the
following steps:
•
Loading the image for the CE code into CE PRAM.
•
Loading the CE data into CE DRAM.
•
Establishing the equation to be applied in EQU.
•
Establishing the accumulation period and number of samples in PRE_SAMPS and SUM_CYCLES.
•
Establishing the number of cycles per ADC mux cycle.
The default configuration is FIR_LEN = 1 (three cycles per conversion) and MUX_DIV = 1 (4 conversions per mux cycle).
There must be thirteen CK32 cycles (see System Timing Diagram, Figure 13). This means that the product of the number of
cycles per ADC conversion and the number of conversions per cycle must be 12 (allowing for one settling cycle).
Alternatively, the 71M6511 can be operated at ten CK32 cycles per ADC mux cycle (MUX_DIV = 2). CE quantities are stated
in this section for MUX_DIV = 2, if they differ from those associated with the default setting.
During operation, the MPU is in charge of controlling the multiplexer cycles, for example by inserting an alternate multiplexer
sequence at regular intervals using MUX_ALT. This enables temperature measurement. The polarity of CHOP must be altered
for each sample. It must also alternate for each alternate multiplexer reading.
The MPU must program CHOP_EN alternately between 01 and 10 on every CE_BUSY interrupt except for the first CE_BUSY
after an XFER_BUSY interrupt. Note that when XFER_BUSY occurs, it will always be at the same time as a CE_BUSY
interrupt.
CE Calculations
The CE performs the precision computations necessary to accurately measure power. These computations include offset
cancellation, phase compensation, product smoothing, product summation, frequency detection, VAR calculation, sag
detection, peak detection, and voltage phase measurement. All data computed by the CE is dependent on the selected meter
equation as given by EQU (in I/O RAM). As a function of EQU, the element components V0 through I2 take on different
meanings.
EQU
(WSUM/VARSUM)
0
VA IA (1 element, 2W 1φ)
1
VA*(IA-IB)/2
(1 element, 3W 1φ)
Page: 65 of 95
Element Input Mapping
Watt & VAR Formula
W0SUM/
VAR0SUM
W1SUM/
VAR1SUM
I0SQSUM
I1SQSUM
VA*IA
VA*IB
IA
IB
VA*(IA-IB)/2
VA*IB
IA-IB
IB
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
CE RAM Locations
CE Front End Data (Raw Data)
Access to the raw data provided by the AFE is possible by reading addresses 0 through 7, as listed below.
Address (HEX)
00
01
02
03
04
05
06
07
Name
IA
VA
IB
TEMP
--
Description
Phase A current
Phase A voltage
Phase B current
Reserved
Reserved
Reserved
Temperature
Reserved
CE Status Word
Since the CE_BUSY interrupt occurs at 2520.6Hz (or at 3276.8Hz when MUX_DIV = 2), it is desirable to minimize the
computation required in the interrupt handler of the MPU. The MPU can read CESTATUS at every CE_BUSY interrupt.
CE
Address
Name
0x51
CESTATUS
Description
See description of CE status word below
The CE Status Word is useful for generating early warnings to the MPU. It contains sag warnings for phase A, as well as F0,
the derived clock operating at the fundamental input frequency. CESTATUS provides information about the status of voltage
and input AC signal frequency, which are useful for generating an early power fail warning to initiate necessary data storage.
CESTATUS represents the status flags for the preceding CE code pass (CE_BUSY interrupt).
Note: The CE does not store sag alarms from one code pass to the next. CESTATUS is refreshed at every CE_BUSY
interrupt and remains valid for up to 100µs after the CE_BUSY interrupt occurs. Unsynchronized read operations of
CESTATUS will yield unreliable results.
The significance of the bits in CESTATUS is shown in the table below:
CESTATUS
[bit]
Name
31-29
Not Used
28
F0
27
RESERVED
26
RESERVED
25
SAG_A
24-0
Not Used
Page: 66 of 95
Description
These unused bits will always be zero.
F0 is a square wave at the exact fundamental input frequency.
Normally zero. Becomes one when VA remains below SAG_THR for SAG_CNT
samples. Will not return to zero until VA rises above SAG_THR.
These unused bits will always be zero.
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
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For generating proper status information, the CE is initialized by the MPU using SAG_THR (default of 80V RMS at the meter
input if VMAX=600V) and SAG_CNT (default 80 samples). Using the default value for SAG_CNT, the peak-to-peak signal has
to be below SAG_THR value for 32 milliseconds to activate the SAG_X status bits.
CE
Address
Name
Default
Description
Meter voltage inputs must be above this threshold to prevent sag alarms.
LSB = VMAX * 3.3243*10-9 V peak.
0x31
SAG_THR
+56,722,300
(0x361837C)
For example, if a sag threshold of 80V RMS is desired,
2
SAG _ THR = VMAX ⋅803.3243
⋅10 −9
0x32
SAG_CNT
Number of consecutive voltage samples below SAG_THR before a sag alarm
is declared. 80*397µs = 31.8ms (for MUX_DIV = 1).
80
CE Transfer Variables
When the MPU receives the XFER_BUSY interrupt, it knows that fresh data is available in the transfer variables. CE transfer
variables are modified during the CE code pass that ends with an XFER_BUSY interrupt. They remain constant throughout
each accumulation interval. In this data sheet, the names of CE transfer variables always end with _X.
Fundamental Power Measurement Variables
The table below describes each transfer variable for fundamental power measurement. All variables are signed 32 bit integers.
Accumulated variables such as WSUM are internally scaled so they have at least 2x margin before overflow when the
integration time is 1 second. Additionally, the hardware will not permit output values to ‘fold back’ upon overflow.
CE
Address
Name
42
RESERVED
43
W0SUM_X
44
W1SUM_X
45
RESERVED
46
RESERVED
47
VAR0SUM_X
48
VAR1SUM_X
49
RESERVED
Description
The sum of Watt samples from each wattmeter element (In_8 is the gain
configured by IA_SHUNT or IB_SHUNT).
LSB = 6.6952*10-13 VMAX IMAX / In_8 Wh (for MUX_DIV = 1)
LSB = 5.1501*10-13 VMAX IMAX / In_8 Wh (for MUX_DIV = 2)
The sum of VAR samples from each wattmeter element (In_8 is the gain
configured by IA_SHUNT or IB_SHUNT).
LSB = 6.6952*10-13 VMAX IMAX / In_8 Wh (for MUX_DIV = 1)
LSB = 5.1501*10-13 VMAX IMAX / In_8 Wh (for MUX_DIV = 2)
WxSUM_X is the Wh value accumulated for element ‘X’ in the last accumulation interval and can be computed based on the
specified LSB value.
For example with VMAX = 600V and IMAX = 208A, LSB (for WxSUM_X ) is 0.08356 µWh (MUX_DIV = 1).
Page: 67 of 95
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V2.6
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Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Instantaneous Power Measurement Variables
The FREQSEL Register selects the input phase used for frequency measurement and for the MAIN_EDGE counter. The
frequency measurement is implemented using the frequency locked loop of the CE for the selected phase.
IxSQSUM_X and VxSQSUM are the squared current and voltage samples acquired during the last accumulation interval.
INSQSUM_X can be used for computing the neutral current.
CE
Address
Name
33
RESERVED
Description
Fundamental frequency.
LSB
41
FREQ_X
or
≡
FS
≈ 0.587 ⋅ 10 − 6 Hz for MUX_DIV = 1
32
2
FS
≈ 0.763 ⋅ 10 −6 Hz for MUX_DIV = 2
2 32
4A
I0SQSUM_X
The sum of squared current samples from each element.
4B
I1SQSUM_X
4C
RESERVED
LSB = 6.6952*10-13 IMAX2 / In_82 A2h (for MUX_DIV = 1)
LSB = 5.1501*10-13 IMAX2 / In_82 A2h (for MUX_DIV = 2)
4D
RESERVED
4E
V0SQSUM_X
4F
RESERVED
50
RESERVED
The sum of squared voltage samples from each element.
LSB= 6.6952*10-13 VMAX2 V2h (for MUX_DIV = 1)
LSB = 5.1501*10-13 VMAX2V2h (for MUX_DIV = 2)
The RMS values can be computed by the MPU from the squared current and voltage samples as per the formulae:
IxRMS =
IxSQSUM ⋅ LSB ⋅ 3600 ⋅ FS
N ACC
VxRMS =
VxSQSUM ⋅ LSB ⋅ 3600 ⋅ FS
N ACC
Note: FS = 2520.6Hz (MUX_DIV = 1) or 3276.8Hz (MUX_DIV = 2)
Other Measurement Parameters
MAINEDGE_X is useful for implementing a real-time clock based on the input AC signal. MAINEDGE_X is the number of halfcycles accounted for in the last accumulated interval for the AC signal of the phase specified in the FREQSEL register.
CE
Address
Name
52
RESERVED
53
RESERVED
55
MAINEDGE_X
Page: 68 of 95
Description
The number of edge crossings of the selected voltage in the previous
accumulation interval. Edge crossings are either direction and are debounced.
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Temperature Measurement and Temperature Compensation
Input variables: TEMP_NOM is the reference value for temperature measurement, i.e. when this value is set with
TEMP_RAW_X at known temperature. The 71M6511/6511H measures temperature with reference to this value.
DEGSCALE is the slope or rate of temperature increase or decrease from the TEMP_NOM for TEMP_X measurement.
PPMC and PPMC2 are temperature compensation coefficients. Their values should reflect the characteristics of the band gap
voltage reference of the chip. PPMC and PPMC2 follow the square law characteristics to compensate for nonlinear
temperature behaviors, when the 71M6511/6511H is in internal temperature compensation mode.
CE
Address
Name
Default
0x11
TEMP_NOM
0
0x30
DEGSCALE
9585
Description
During calibration, the value of TEMP_RAW_X should be placed in
TEMP_NOM.
Scale factor for TEMP_X.
TEMP_X = -DEGSCALE*2-22*(TEMP_RAW_X-TEMP_NOM).
Should be 15 or 0. When 15, causes the CE to ignore internal temperature
compensation and permits the MPU to control GAIN_ADJ. When internal
temperature compensation is selected, GAIN_ADJ will be:
0x38
0x39
0x3A
EXT_TEMP
PPMC
PPMC2
0
0
0
 TEMP _ X ⋅ PPMC TEMP _ X 2 ⋅ PPMC2 

GAIN _ ADJ = 16384 + floor1 +
+
214
2 23


Default is 0 (internal compensation).
Linear temperature compensation factor. Equals the linear temperature coefficient (PPM/°C) of VREF multiplied by 26.84, or TC1 (expressed in µV/°C,
see Electrical Specifications) multiplied by 22.46. A positive value will cause
the meter to run faster when hot. The compensation factor affects both V and
I and will therefore have a double effect on products.
Square-law temperature compensation factor. Equals the square-law temperature coefficient (PPM/°C2) of VREF multiplied by 1374, or TC2 (expressed in µV/°C2, see Electrical Specifications) multiplied by 1150.1. A positive value will cause the meter to run faster when hot. The compensation
factor affects both V and I and will therefore have a double effect on products.
EXT_TEMP allows the MPU to select between direct control of GAIN_ADJ or management of GAIN_ADJ by the CE, based on
TEMP_X and the temperature correction coefficients PPMC and PPMC2.
Output variables: TEMP_X is the temperature measurement from reference temperature of TEMP_NOM. TEMP_X is
computed using TEMP_RAW_X and DEGSCALE. This quantity is positive when the temperature is above the reference and is
negative for cold temperatures.
TEMP_RAW_X is the raw processed value from ADC output and is the fundamental quantity for temperature measurement.
TEMP_RAW_X is less than TEMP_NOM at higher temperatures. TEMP_RAW_X is more than TEMP_NOM for cooler
temperatures than reference temperature.
GAIN_ADJ is a scaling factor for power measurements based on temperature (when in internal temperature compensation
mode). In general, for higher temperatures it is lower than 16384 and higher than 16384 for lower temperatures. GAIN_ADJ is
mainly dependent on the PPMC, PPMC2 and TEMP_X register values. This parameter is automatically computed by the CE
and is used by the CE for temperature compensation.
Page: 69 of 95
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Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
CE
Address
Name
0x40
TEMP_X
0x54
TEMP_RAW_X
Filtered, unscaled reading from temperature sensor. This value should be
written to TEMP_NOM during meter calibration.
0x2E
GAIN_ADJ
Scales all voltage and current inputs. 16384 provides unity gain. Default is
16384. If EXT_TMP = 0, GAIN_ADJ is updated by the CE.
Description
Deviation from Calibration temperature. LSB = 0.1 0C.
Pulse Generation
Input variables: The combination of the PULSE_SLOW and PULSE_FAST parameters control the speed of the pulse rate.
The default values of 1 and 1 will maintain the original pulse rate given by the Kh equation.
WRATE controls the number of pulses that are generated per measured Wh and VARh quantities. The lower WRATE it is the
slower is the pulse rate for measured power quantity. The metering constant Kh is derived from WRATE as the amount of
energy measured for each pulse. That is, if Kh = 1Wh/pulse, a power applied to the meter of 120V and 30A results in one
pulse per second. If the load is 240V at 150A, ten pulses per second will be generated.
Control is transferred to the MPU for pulse generation if EXT_PULSE > 0. In this case, the pulse rate is determined by
APULSEW and APULSER. The MPU has to load the source for pulse generation in APULSEW and APULSER to generate
pulses. Irrespective of the EXT_PULSE, status the output pulse rate controlled by APULSEW and APULSER is implemented
by the CE only. By setting EXT_PULSE > 0, the MPU is providing the source for pulse generation. If EXT_PULSE is negative,
W0SUM_X and VAR0SUM_X are the default pulse generation sources. In this case, creep cannot be controlled since it is an
MPU function.
The maximum pulse rate is FS /2= 1260.3Hz (MUX_DIV = 1).
PULSE_WIDTH allows adjustment of the pulse width for compatibility with calibration and other external equipment. When
MUX_DIV = 1, the minimum pulse width possible is 397µs.
The maximum time jitter is 397µs (for MUX_DIV = 1) and is independent of the number of pulses measured. Thus, if the pulse
generator is monitored for 1 second, the peak jitter is 397PPM. After 10 seconds, the peak jitter is 39.7PPM. The average jitter
is always zero. If it is attempted to drive either pulse generator faster than its maximum rate, it will simply output at its
maximum rate without exhibiting any roll-over characteristics. The actual pulse rate, using WSUM as an example, is:
RATE =
X ⋅ WRATE ⋅ WSUM ⋅ FS
Hz
2 46
Where FS = 2520.6Hz (sampling frequency for MUX_DIV = 1) or 3276.8Hz (sampling frequency for MUX_DIV = 2) and X is the
pulse gain factor derived from CE variables PULSE_SLOW and PULSE_FAST (see table below).
Page: 70 of 95
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Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
CE
Address
Name
Default
Description
When PULSE_SLOW > 0, the pulse generator input is reduced 64x.
When PULSE_FAST > 0, the pulse generator input is increased 16x.
0x28
PULSE_SLOW
1
These two parameters control the pulse gain factor X (see table below). Allowed
values are either 1 or –1.
X
PULSE_SLOW
PULSE_FAST
2
-1
-1
6
-1
1
1.5 * 2 = 6
0x29
PULSE_FAST
1
1.5 * 2 = 96
-4
1.5 * 2 = 0.09375
1
-1
1.5
1 (default)
1 (default)
0x2D
WRATE
1556
Kh =
VMAX*IMAX*47.1132 / (In_8*WRATE*NACC*X) Wh/pulse (for MUX_DIV = 1).
VMAX*IMAX*36.2409 / (In_8*WRATE*NACC*X) Wh/pulse (for MUX_DIV = 2).
0x36
SUM_PRE
2520
PRE_SAMPS * SUM_CYCLES. This variable is also called NACC.
0x37
EXT_PULSE
15
Should be 15 or 0. When zero, causes the pulse generators to respond to
WSUM_X and VARSUM_X. Otherwise, the generators respond to values the
MPU places in APULSEW and APULSER.
50
The maximum pulse width (low-going pulse) is:
(2 * PULSE_WIDTH + 1) * 397µs (for MUX_DIV = 1)
(2 * PULSE_WIDTH + 1) * 305µs (for MUX_DIV = 2)
0 is a legitimate value.
0
Wh pulse generator input, to be updated by the MPU when using external pulse
generation (see DIO_PW bit). The output pulse rate is:
APULSEW * FS * 2-32 * WRATE * 2-14
This input is buffered and can be updated by the MPU during a computation interval. The change will take effect at the beginning of the next interval.
0
VARh pulse generator input to be updated by the MPU when using external
pulse generation (see DIO_PV bit). The output pulse rate is:
APULSER * FS*2-32 * WRATE * 2-14
This input is buffered and can be updated by the MPU during a computation interval. The change will take effect at the beginning of the next interval.
0x3C
PULSE_WIDTH
0x26
0x27
Page: 71 of 95
APULSEW
APULSER
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V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Current Shunt Variables
Input variables: IA_SHUNT and IB_SHUNT can configure the current inputs to accept shunt resistor sensors. In this case the
CE provides an additional gain of 8 to the current inputs. This will enable the pulse rate to change by 8 times. In order to
maintain a normal pulse rate WRATE may have to be decreased by 8 times. Whenever IA_SHUNT or IB_SHUNT are set to 1
or a positive number, In_8 is assigned a value of 8 in the equation for Kh.
CE
Address
Name
Default
2A
IA_SHUNT
-1
2B
IB_SHUNT
-1
2C
RESERVED
Description
When +1, these variables increase the respective current gain by 8. The
gain factor controlled by In_SHUNT is referred to as In_8 throughout this
document. Allowed values are 1 or –1. For example, if IB_SHUNT=-1, IB_8
= 1, if IB_SHUNT = 1, IB_8 = 8.
IA_SHUNT corresponds to IA_8, IB_SHUNT corresponds to IB_8.
CE Calibration Parameters
The table below lists the parameters that are typically entered to affect calibration of meter accuracy.
CE
Address
Name
Default
8
CAL_IA
16384
9
CAL_VA
16384
A
CAL_IB
16384
B
RESERVED
C
RESERVED
D
RESERVED
E
PHADJ_A
0
F
PHADJ_B
0
Description
These constants control the gain of their respective channels. The nominal
value for each parameters is 214 = 16384. The gain of each channel is directly
proportional to its CAL parameter. Thus, if the gain of a channel is 1% slow,
CAL should be scaled by 1/(1 – 0.01).
These two constants control the CT phase compensation. No compensation
occurs when PHADJ_X = 0. As PHADJ_X is increased, more compensation
(lag) is introduced. Range: ±215 – 1. If it is desired to delay the current by the
angle Φ:
PHADJ _ X = 2 20
a ⋅ TANΦ
b − c ⋅ TANΦ
a = 1 + (1 − 2 −9 ) 2 − 2(1 − 2 −9 ) cos( 2πF0T )
10
RESERVED
0
F0T =
F0
FS
b = (1 − 2 −9 ) sin( 2πF0T )
c = 1 − (1 − 2 −9 ) cos( 2πF0T )
Page: 72 of 95
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Single-Phase Energy Meter IC
DATA SHEET
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Other CE Parameters
The table below shows CE parameters used for suppression of noise due to scaling and truncation effects as well as scaling
factors.
CE
Address
Name
Default
2F
22
QUANTA
QUANTB
0
0
These parameters are added to the Watt calculation to compensate for input
noise and truncation.
LSB=(VMAX*IMAX / IA_8) *7.4162*10-10 W for phase A, and
LSB=(VMAX*IMAX / IB_8) *7.4162*10-10 W for phase B
34
24
QUANT_VARA
QUANT_VARB
0
0
These parameters are added to the VAR calculation to compensate for input
noise and truncation.
LSB = (VMAX*IMAX / IA_8) * 7.4162*10-10 W for phase A, and
LSB = (VMAX*IMAX / IB_8) * 7.4162*10-10 W for phase B
35
23
3B
Page: 73 of 95
QUANT_IA
QUANT_IB
KVAR
0
0
Description
These parameters are added to compensate for input noise and truncation in
the squaring calculations for I2 and V2.
LSB=VMAX2*7.4162*10-10 V2,
LSB= (IMAX2/IA_82)*7.4162*10-10 A2 for phase A and
LSB= (IMAX2/IB_82)*7.4162*10-10 A2 for phase B.
Scale factor for the VAR calculation. The default value of KVAR should never
need to be changed.
6448
12880
for MUX_DIV = 1
for MUX_DIV = 2
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
TYPICAL PERFORMANCE DATA
Wh Accuracy at Room Temperature
0.2
0 Deg
60 Deg
0.15
-60 Deg
%Error
0.1
180 Deg
0.05
1
3
0.3
0
200
10
25 30
100
-0.05
-0.1
-0.15
-0.2
0.1
1
10
100
A
1000
Figure 24: Wh Accuracy, 0.3A - 200A/240V
% Error
VARh Accuracy at Room Temperature
0.2
0.15
0.1
0.05
0
-0.05
-0.1
-0.15
-0.2
90 Deg
150 Deg
3
270 Deg
10
25
1
30
0.3
100
0.1
1
10
200
100
A
1000
Figure 25: VARh Accuracy for 0.3A to 200A/240V Performance
Error(%)
Linearity over Temperature
0.5
0.4
0.3
0.2
0.1
0
-0.1
-0.2
-0.3
-0.4
-0.5
-5C
-40C
25C
55C
85C
0.1
1
10
100
1000
Current [A]
Figure 26: 71M6511H Wh Accuracy over Current at Various Temperatures
Page: 74 of 95
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Single-Phase Energy Meter IC
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Harmonic Performance
2
1
0
Error [%]
-1
-2
-3
50Hz Harmonic Data
60Hz Harmonic Data
-4
-5
-6
-7
-8
1
3
5
7
9
11
13
15
17
19
21
23
25
Harmonic
Test performed at current distortion amplitude of 40% and voltage distortion amplitude of 10% as per IEC 62053, part 22.
Figure 27: Meter Accuracy over Harmonics at 240V, 30A
Accuracy [PPM/°C]
Meter Accuracy over Temperature (71M6511H)
Limit
15
Limit
10
typical chip
5
0
-5
-10
-15
-60
-40
-20
0
20
40
60
80
100
Temperature [°C]
Figure 28: Typical Meter Accuracy over Temperature Relative to 25°C (w/ Temperature Compensation)
Page: 75 of 95
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Single-Phase Energy Meter IC
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APPLICATION INFORMATION
Connection of Sensors (CT, Resistive Shunt, Rogowski Coil)
Figure 29 and Figure 30 show how resistive dividers, current transformers, restive shunts, and Rogowski coils are connected
to the voltage and current inputs of the 71M6511.
Vout = R * Iout = R * Iin/N
core
VA = Vin * Rout/(Rout + Rin)
VA
Iout
Iin
R
Rin
Vin
Iin
IA
Vout
Rout
V3P3
1/N
Filter
Iout
Figure 29: Resistive Voltage Divider (left), Current Transformer (right)
Vout = R * Iin
Iin
Iin
IA
R
Vout
1/N
Vout = dIin /dt
Vout
IA
R
V3P3
VC
V3P3
Iin
Figure 30: Resistive Shunt (left), Rogowski Coil (right)
Distinction between 71M6511 and 71M6511H Parts
71M6511H parts go through a process of trimming and characterization during production that make them suitable to highaccuracy applications.
The first process applied to the 71M6511H is the trimming of the reference voltage, which is guaranteed to have accuracy over
temperature of better that ±10PPM/°C.
The second process applied to the 71M6511H is the characterization of the reference voltage over temperature. The
coefficients for the reference voltage are stored in so-called trim fuses (I/O RAM registers TRIMBGA, TRIMBGB, TRIMM[2:0].
The MPU program can read these trim fuses and calculate the correction coefficients PPM1 and PPM2 per the formulae given
in the Performance Specifications section (VREF, VBIAS). See the Temperature Compensation section for details.
The fuse TRIMBGB is non-zero for the 71M6511H part and zero for the 71M6511 part.
Trim fuse information is not available for non-H parts. Thus, the standard are to be applied. These settings are:
•
PPMC = TC1 * 22.46 = –149
•
PPMC2 = TC2 * 1150.1 = –392
Page: 76 of 95
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Temperature Compensation and Mains Frequency Stabilization for the RTC
The accuracy of the RTC depends on the stability of the external crystal. Crystals vary in terms of initial accuracy as well as in
terms of behavior over temperature. The flexibility provided by the MPU allows for compensation of the RTC using the substrate temperature. To achieve this, the crystal has to be characterized over temperature and the three coefficients Y_CAL,
Y_CALC, and Y_CAL_C2 have to be calculated. Provided the IC substrate temperatures tracks the crystal temperature, the
coefficients can be used in the MPU firmware to trigger occasional corrections of the RTC seconds count, using the
RTC_DEC_SEC or RTC_INC_SEC registers in I/O RAM.
It is not recommended to measure crystal frequency directly due to the error introduced by the measurement probes. A
practical method to measure the crystal frequency (when installed on the PCB with the 71M6511) is to have a DIO pin toggle
every second, based on the RTC interrupt, with all other interrupts disabled. When this signal is measured with a precision
timer, the crystal frequency can be obtained from the measured time period t (in µs):
f = 32768
10 6 µs
t
Example: Let us assume a crystal characterized by the measurements shown in Table 62. The values show that even at
nominal temperature (the temperature at which the chip was calibrated for energy), the deviation from the ideal crystal
frequency is 11.6 PPM, resulting in about one second inaccuracy per day, i.e. more than some standards allow.
Deviation from
Nominal
Temperature [°C]
Measured
Frequency [Hz]
Deviation from
Nominal
Frequency [PPM]
+50
32767.98
-0.61
+25
32768.28
8.545
0
32768.38
11.597
-25
32768.08
2.441
-50
32767.58
-12.817
Table 62: Frequency over Temperature
As Figure 31 shows, even a constant compensation would not bring much improvement, since the temperature characteristics
of the crystal are a mix of constant, linear, and quadratic effects (in commercially available crystals, the constant and quadratic
effects are dominant).
32768.5
32768.4
32768.3
32768.2
32768.1
32768
32767.9
32767.8
32767.7
32767.6
32767.5
-50
-25
0
25
50
Figure 31: Crystal Frequency over Temperature
The temperature characteristics of the crystal are obtained from the curve in Figure 31 by curve-fitting the PPM deviations. A
fairly close curve fit is achieved with the coefficients a = 10.89, b = 0.122, and c = –0.00714 (see Figure 32).
Page: 77 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
When applying the inverted coefficients, a curve (see Figure 32) will result that effectively neutralizes the original crystal
characteristics. The frequencies were calculated using the fit coefficients as follows:
a
b
c 

f = f nom ⋅ 1 + 6 + T 6 + T 2 6 
10
10 
 10
32768.5
32768.4
32768.3
32768.2
32768.1
32768
32767.9
32767.8
crystal
32767.7
curve fit
32767.6
inverse curve
32767.5
-50
-25
0
25
50
Figure 32: Crystal Compensation
The MPU Demo Code supplied with the TERIDIAN Demo Kits has a direct interface for these coefficients and it directly controls the RTC_DEC_SEC or RTC_INC_SEC registers. The Demo Code uses the coefficients in the following form:
CORRECTION ( ppm) =
Y _ CAL
Y _ CALC
Y _ CALC 2
+T ⋅
+T2 ⋅
10
100
1000
Note that the coefficients are scaled by 10, 100, and 1000 to provide more resolution. For our example case, the coefficients
would then become (after rounding, since the Demo Code accepts only integers):
Y_CAL = 109, Y_CALC = 12, Y_CALC2 = 7
Alternatively, the mains frequency may be used to stabilize or check the function of the RTC. For this purpose, the CE provides
a count of the zero crossings detected for the selected line voltage in the MAIN_EDGE_X address. This count is equivalent to
twice the line frequency, and can be used to synchronize and/or correct the RTC.
External Temperature Compensation
In a production electricity meter, the 71M6511 or 71M6511H is not the only component contributing to temperature dependency. In fact, a whole range of components (e.g. current transformers, resistor dividers, power sources, filter capacitors)
will exhibit slight or pronounced temperature effects. Since the output of the on-chip temperature sensor is accessible to the
MPU, temperature-compensation mechanisms with great flexibility, i.e. beyond the capabilities implemented in the CE, are
possible.
Temperature Measurement
Temperature measurement can be implemented with the following steps:
1)
At a known temperature TN, read the TEMP_RAW register of the CE and write the value into TEMP_NOM.
2)
Read the TEMP_X register at the known temperature. The obtained value should be <±0.1°C.
3)
The temperature T (in °C) at any environment can be obtained by reading TEMP_X and applying the following
formula:
T = TN +
Page: 78 of 95
TEMP _ X
10
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Connecting LCDs
The 71M6511 has a LCD controller on-chip capable of controlling static or multiplexed LCDs. Figure 33 shows the basic
connection for a LCD.
71M6511
LCD
segments
commons
Figure 33: Connecting LCDs
Figure 34 shows how 5V LCDs can be operated even when a 5V supply is not available. Setting the I/O RAM register
LCD_BSTEN to 1 starts the on-chip boost circuitry that will output an AC frequency on the VDRV pin. Using a small coupling
capacitor, two general-purpose diodes and a reservoir capacitor, a 5VDC voltage is generated which can be fed back into the
VLCD pin of the 71M6511. The LCD drivers are enabled with the I/O register LCD_ON; I/O register LCD_FS is used to adjust
contrast, and LCD_MODE selects the operation mode (LCD type).
V3P3
71M6511
LCD_BSTEN
V3P3
VDRV
5VDC
VLCD
Contrast
LCD_FS
ON/OFF
LCD_EN
LCD type LCD_MODE
5V LCD
segments
commons
Figure 34: LCD Boost Circuit
Page: 79 of 95
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V2.6
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Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Connecting I2C EEPROMs
I2C EEPROMs or other I2C compatible devices should be connected to the DIO pins DIO4 and DIO5, as shown in Figure 35.
Pull-up resistors of roughly 3kΩ to V3P3 should be used for both SCL and SDA signals. The DIO_EEX register in I/O RAM
must be set to 1 in order to convert the DIO pins DIO4 and DIO5 to I2C pins SCL and SDA.
3kΩ
71M6511
V3P3
3kΩ
EEPROM
DIO4
SCL
DIO5
SDA
Figure 35: EEPROM Connection
Connecting 5V Devices
In general, all pins of the 71M6511 are compatible with external 5V devices. The exceptions are the power supply pins and the
RX pin of the UART (see section Electrical Specifications).
V3P3
71M651X
R1 = 100kΩ
VIN
RX
Figure 36: Interfacing RX to a 0-5V Signal
Figure 36 shows how a 5V signal from an external device can be safely interfaced to the RX pin.
Page: 80 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Optical Interface
The pins OPT_TX and OPT_RX can be used for a regular serial interface, e.g. by connecting a RS_232 transceiver, or they
can be used to directly operate optical components, e.g. an infrared diode and phototransistor implementing a FLAG interface.
Figure 37 shows the basic connections. The OPT_TX pin becomes active when the I/O RAM register OPT_TXDIS is set to 0.
V3P3
R1
71M6511
OPT_RX
100pF 100kΩ
Phototransistor
V3P3
R2
OPT_TX
LED
Figure 37: Connection for Optical Components
Connecting V1 and Reset Pins
A voltage divider should be used to establish a safe range for V1 when the meter is in mission mode (V1 must be lower than
2.9V in all cases in order to keep the hardware watchdog timer enabled). For proper debugging or loading code into the
71M6511 mounted on a PCB, it is necessary to have a provision like the header shown above R1 in Figure 38. A shorting
jumper on this header pulls V1 up to V3P3, disabling the hardware watchdog timer. C1 helps suppressing ESD.
R3
R1
10kΩ
Vin
R2
C1
100pF
V1
Figure 38: Voltage Divider for V1
Even though a functional meter will not necessarily need a reset switch, it is useful to have a reset pushbutton for prototyping.
When a circuit is used in an EMI environment, the RESETZ pin should be supported by the external components shown in
Figure 39. R1 should be in the range of 200Ω, R2 should be around 10Ω. The capacitor C1 should be 1nF. R1 and C1 should
be mounted as close as possible to the IC. In cases where the trace from the pushbutton switch to the RESETZ pin poses a
problem, R2 can be removed.
Page: 81 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
71M6511
V3P3
V3P3
10Ω
R1
200Ω
RESETZ
R2
Pushbutton
C1
1nF
DGND
Figure 39: External Components for RESETZ
Flash Programming
Operational or test code can be programmed into the flash memory using either an in-circuit emulator or the Flash Download
Board Module (FDBM) available from TERIDIAN. The flash programming procedure uses the E_RTS, E_RXTX, and E_TCLK
pins.
MPU Firmware Library
All application-specific MPU functions mentioned above under “Application Information” are available from TERIDIAN as a
standard ANSI C library and as ANSI “C” source code. The code is available as part of the Demonstration Kit for the 71M6511
and 71M6511H ICs. The Demonstration Kits come with the 71M6511 or 71M6511H IC preprogrammed with demo firmware
mounted on a functional sample meter PCB (Demo Board). The Demo Boards allow for quick and efficient evaluation of the IC
without having to write firmware or having to supply an in-circuit emulator (ICE).
A reference guide for firmware development on the 71M6511 and 71M6511H is available as a separate document (Software
User’s Guide, “SUG”). The User’s Manuals supplied with the Demo Kits contain MPU address maps for the demo code as well
as other useful information, such as sample calibration procedures.
Page: 82 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
SPECIFICATIONS
Electrical Specifications
ABSOLUTE MAXIMUM RATINGS
Supplies and Ground Pins:
−0.5V to 4.6V
0V to 0.5V
-0.5V to 7V
-0.5V to 4.6V
-0.5V to +0.5V
V3P3D, V3P3A
| V3P3D - V3P3A |
VLCD
VBAT
GNDD
Analog Output Pins:
-1mA to 1mA,
-0.5 to V3P3A+0.5V
-1mA to 1mA,
-0.5V to 3.0V
VREF, VBIAS
V2P5
Analog Input Pins:
IA, VA, IB
XIN, XOUT
RX
-0.5V to V3P3A+0.5V
-0.5V to 3.0V
-0.5V to 3.6V
-1mA to 1mA
-0.5 to V3P3A+0.5V
OPT_RX
Digital Input Pins:
DIO4-11, DIO14-17, E_RXTX, E_RST
-0.5 to 6V
TEST, RESETZ
-0.5 to V3P3D+0.5V
All Other Pins:
-5mA to 5mA
Input pins
-0.5V to V3P3D+0.5V
-30mA to 30mA
Output pins
-0.5 to V3P3D+0.5V
Temperature:
Operating junction temperature (peak, 100ms)
Operating junction temperature (continuous)
140 °C
125 °C
Storage temperature
−45 °C to 165 °C
250 °C
Solder temperature – 10 second duration
ESD Stress:
Pins IA, VA, IB, RX, TX, E_RST, E_TCLK, E_RXTX
All other pins
6kV
2kV
Stresses beyond Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only and functional
operation at these or any other conditions beyond those indicated under “recommended operating conditions” is not implied. Exposure to
absolute-maximum-rated conditions for extended periods may affect device reliability. All voltages are with respect to GNDA.
Page: 83 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
RECOMMENDED OPERATING CONDITIONS
PARAMETER
CONDITION
MIN
TYP
MAX
UNIT
3.3V Supply Voltage
(V3P3A, V3P3D) †
Normal Operation
3.0
3.3
3.6
V
0
3.45
V
2.9
5.5
V
Battery Backup
VLCD
No Battery
VBAT
Battery Backup
Operating Temperature
Externally Connect to V3P3D
2.0
3.8
V
-40
85
ºC
†
V3P3A and V3P3D should be shorted together on the circuit board. GNDA and GNDD should also be shorted on the circuit board.
LOGIC LEVELS
PARAMETER
MAX
UNIT
Digital high-level input voltage, VIH
CONDITION
2
V3P3D
V
Digital low-level input voltage, VIL
−0.3
0.8
V
ILOAD = 1mA
V3P3D
–0.4
V3P3D
V
ILOAD = 15mA
V3P3D0.6
ILOAD = 1mA
0
Digital high-level output voltage VOH
Digital low-level output voltage VOL
Input pull-up current, IIL
MIN
TYP
ILOAD = 15mA
V
0.4
V
0.8
V
VIN=0V
RESETZ
E_RXTX, E_RST
10
10
100
100
µA
µA
Other digital inputs
-1
1
µA
TEST
10
100
µA
Other digital inputs
-1
1
µA
Input pull down current, IIH
Page: 84 of 95
VIN=V3P3D
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
SUPPLY CURRENT
PARAMETER
CONDITION
TYP
MAX
UNIT
6.4
9.5
mA
V3P3A current
Normal Operation,
V3P3A=V3P3D=VLCD=3.3V
3.7
4.3
mA
V3P3D current
CKMPU=614kHz
2.5
4.8
mA
VLCD current
VBAT=3.6V
0.2
0.4
mA
300
nA
V3P3A + V3P3D + VLCD current
MIN
No Flash memory write
VBAT current
-300
Normal Operation,
V3P3A=V3P3D=VLCD=3.3V
VBAT=3.6V, no Flash memory
write
V3P3D current
CKMPU=1,228kHz
CKMPU=2,456kHz
CKMPU=4,912kHz
mA
mA
mA
2.9
3.6
5.1
Power save/sleep mode
V3P3A=V3P3D=VLCD=3.3V,
CE, ADC, E_TCLK, VREF disabled
CKMPU=153.5kHz
CKMPU=38.4kHz
V3P3A + V3P3D current
6
4.9
Normal Operation as above,
except write Flash at maximum
rate.
V3P3D current, Write Flash
Battery backup,
VBAT current,
7
≤25°C
V3P3A=V3P3D=VLCD=0V
VBAT=3.6V
fOSC = 32kHz
7
85°C
mA
mA
mA
2
4
µA
4
12
µA
TYP
MAX
UNIT
440
mV
+3
mV/V
2.5V VOLTAGE REGULATOR
Unless otherwise specified, load = 5mA
PARAMETER
Voltage overhead V3P3-V2P5
PSSR ∆V2P5/∆V3P3
Page: 85 of 95
CONDITION
Reduce V3P3 until V2P5
drops 200mV
RESETZ=1, iload=0
MIN
-3
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
VREF, VBIAS
Unless otherwise specified, VREF_DIS=0
PARAMETER
VREF output voltage, VNOM(25)
VREF chop step
VREF output impedance
A
VNOM definition
CONDITION
Ta = 22ºC
MIN
1.193
TYP
1.195
VREF_CAL = 1,
ILOAD = 10µA, -10µA
2
VNOM(T) = VREF(22) + (T–22)TC1 + (T–22) TC2
-- If TRIMBGA and TRIMBGB available (6511H) --
VREF temperature coefficients
TC1 (linear)
TC2 (quadratic)
TRIMBGA, TRIMBGB, TRIMM[2:0]: See
TRIMSEL, TRIM registers
MAX
1.197
40
UNIT
V
mV
2.5
kΩ
V
x(33-0.28y) + 0.33y + 7.9
x(0.02-0.0002y) – 0.46
where x = 0.1TRIMBGB - 0.14(TRIMM[2:0]+0.5),
µV/°C
µV/°C2
TEMP _ NOM
− 500TRIM _ BGA − 370000
4.7404
y=
900
VREF(T) deviation from VNOM(T)
VREF(T ) − VNOM (T )
106
VNOM
max(| T − 22 |,40)
-10
-- If TRIMBGA and TRIMBGB not available (6511) -VREF temperature coefficients
TC1 (linear)
TC2 (quadratic)
VREF(T) deviation from VNOM(T)
VREF(T ) − VNOM (T )
106
VNOM
max(| T − 22 |,40)
Ta = -40ºC to +85ºC
VREF aging
Ta = 25ºC
+40
ppm/ºC
(+1%)
(+2%)
500
ppm/
year
V
V
Ω
MAX
1
3
UNIT
µW
pF
5
5
25
pF
pF
kHz
±25
1.5
1.5
240
ppm/ºC
µV/ºC
µV/°C2
7.0
-0.341
-40
Ta = 25ºC
(-1%)
Ta = -40ºC to 85ºC
(-2%)
ILOAD = 1mA, -1mA
VBIAS output impedance
A
This relationship describes the nominal behavior of VREF at different temperatures.
VBIAS output voltage
10
CRYSTAL OSCILLATOR
Crystal is disconnected. Test load is series 200pF, 100kΩ connected between DGND and XOUT.
PARAMETER
CONDITION
MIN
TYP
Maximum Output Power to Crystal4
Crystal connected
XIN to XOUT Capacitance1
Capacitance to DGND1
XIN
XOUT
Watchdog RTC_OK threshold
Page: 86 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
ADC CONVERTER, VDD REFERENCED
FIR_LEN=0, VREF_DIS=0, VDDREFZ=0
PARAMETER
Recommended Input Range
(Vin-V3P3A)
Voltage to Current Crosstalk:
CONDITION
MIN
TYP
MAX
UNIT
mV
peak
-250
250
-10
10
µV/V
40
-75
-90
90
dB
dB
kΩ
Vin = 200mV peak, 65Hz,
on VA
10 6 *Vcrosstalk
cos(∠Vin − ∠Vcrosstalk ) Vcrosstalk = largest
Vin
measurement on IA or IB
Vin=65Hz,
64kpts FFT, BlackmanHarris window
Vin=65Hz
THD (First 10 harmonics)
250mV- peak
20mV- peak
Input Impedance
Temperature coefficient of Input
Impedance
LSB size
Digital Full Scale
ADC Gain Error versus
%Power Supply Variation
Vin=65Hz
FIR_LEN=1
1.7
Ω/°C
150
nV/LSB
LSB
±2097152
Vin=200mV peak, 65Hz
V3P3A=3.0v, 3.6V
10 6 ∆Nout PK 357nV / VIN
100 ∆V 3P3 A / 3.3
-10
Input Offset (Vin-V3P3A)
50
ppm/%
10
mV
OPTICAL INTERFACE
PARAMETER
OPT_TX VOH (V3P3D-OPT_TX)
OPT_TX VOL
OPT_RX Vin Threshold
(VinRISING+VinFALLING)/2
OPT_RX Vin Hysteresis
(VinRISING-VinFALLING)
OPT_RX input impedance
CONDITION
ISOURCE=1mA
ISINK=20mA
MIN
TYP
MAX
0.4
0.7
UNIT
V
V
200
250
300
mV
30
mV
5
|Vin|≤300mV
1
MΩ
TEMPERATURE SENSOR
PARAMETER
Nominal Sensitivity (Sn)4
Nominal Offset (Nn) 4
Temperature Error
1
ERR = (T − 25) −
Page: 87 of 95
( N (T ) − N (25))
Sn
CONDITION
TA=25ºC, TA=75ºC
Nominal relationship:
N(T)= Sn*T+Nn
MIN
TA = -40ºC to +85ºC
-3
TYP
-900
MAX
400000
© 2005-2007 TERIDIAN Semiconductor Corporation
UNIT
LSB/ºC
LSB
3
ºC
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
LCD BOOST
PARAMETER
VDRV Frequency
VDRV Sink Current
VDRV Source Current
VLCD Target Voltage
VLCD Input Current
CONDITION
Vol=1.5V
Voh=1.5V
MIN
TYP
OSC/2
1.2
1.2
4.5
VLCD=5.0V, LCD_FS=1F,
LCD_MODE=0,1,2,3
LCD_BSTEN=1
MAX
2.75
2.6
5.5
UNIT
Hz
mA
mA
V
450
µA
MAX
0
0.2
UNIT
V
V
+10
+10
%
%
+15
+10
30
%
%
kΩ
LCD DRIVERS
Applies to all COM and SEG pins. Unless otherwise stated, VLCD=5.0V, LCD_FS=1F
CONDITION
PARAMETER
MIN
VLC0 Max Voltage (LCD_FS =1F)
With respect to VLCD
-0.2
VLC0 Min Voltage (LCD_FS =00)
With respect to VLCD*0.7
-0.2
VLC1 Voltage,
-10
With respect to 2*VLCD/3
1/3 bias
-10
With respect to VLCD/2
½ bias
VLC0 Voltage,
-15
With respect to VLCD/3
1/3 bias
-10
With respect to VLCD/2
½ bias
Output Impedance
∆ILOAD=10µA
TYP
RTC
PARAMETER
Range for date
CONDITION
MIN
2000
TYP
-
MAX
2255
UNIT
year
CONDITION
MIN
5
TYP
MAX
1
UNIT
µs
µs
MAX
UNIT
-20
15
mV
Vin = VBIAS - 100mV
0.8
1.2
µA
+100mV overdrive
2
-400
15
-10
µs
mV
RESETZ
PARAMETER
Reset pulse width
Reset pulse fall time
COMPARATORS
PARAMETER
Offset Voltage
V1-VBIAS
Hysteresis Current
V1
Response Time
V1
WD Disable Threshold (V1-V3P3A)
Page: 88 of 95
CONDITION
MIN
TYP
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
RAM AND FLASH MEMORY
PARAMETER
CE RAM wait states
Flash write cycles
Flash data retention
Flash data retention
Flash byte writes between page or mass
erase operations
CONDITION
CKMPU = 4.9MHz
CKMPU = 1.25MHz
-40°C to +85°C
85°C
25°C
MIN
5
2
20,000
10
100
TYP
MAX
UNIT
Cycles
Cycles
Cycles
Years
Years
2
Cycles
MAX
42
20
200
UNIT
µs
ms
ms
2
Cycles
MAX
UNIT
FLASH MEMORY TIMING
PARAMETER
Write Time per Byte
Page Erase (512 bytes)
Mass Erase
Flash byte writes between page or mass
erase operations
CONDITION
MIN
TYP
EEPROM INTERFACE
PARAMETER
CONDITION
CKMPU=4.9MHz, Using
interrupts
CKMPU=4.9MHz, “bitbanging” DIO4/5
Write Clock frequency
MIN
TYP
78
kHz
150
kHz
FOOTNOTES
1
This parameter is has been verified in production samples, but is not measured in production.
This parameter is has been verified in production samples, but is measured in production only at DC.
3
This parameter is measured in production at the limits of the specified operating temperature.
4
This parameter defines a nominal relationship rather than a measured parameter. Correct circuit operation is verified with other specs
that use this nominal relationship as a reference.
2
Recommended External Components
NAME
C1
C2
FROM
V3P3A
V3P3D
TO
AGND
DGND
XTAL
XIN
XOUT
CXS
CXL
CBIAS
CBST1
C2P5
CBST2
XIN
XOUT
VBIAS
VDRV
V2P5
VLCD
AGND
AGND
AGND
External
DGND
DGND
Page: 89 of 95
FUNCTION
Bypass capacitor for 3.3V supply
Bypass capacitor for 3.3V supply
32.768kHz crystal. Electrically similar to ECS
ECX-3TA series
Load capacitor for crystal (depends on crystal
specs and board parasitics).
Bypass capacitor for VBIAS
Boost charging capacitor
Bypass capacitor for V2P5
Boost bypass capacitor
© 2005-2007 TERIDIAN Semiconductor Corporation
VALUE
≥0.1±20%
≥0.1±20%
UNIT
µF
µF
32.768
kHz
22±10%
22±10%
≥1000±20%
33±20%
≥0.1±20%
≥0.22±20%
pF
pF
pF
nF
µF
µF
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Packaging Information
64-Pin LQFP PACKAGE OUTLINE (Bottom View).
NOTE: Controlling dimensions are in mm.
11.7
12.3
11.7
+
12.3
PIN No. 1 Indicator
9.8
10.2
0.60 Typ.
Page: 90 of 95
0.50 Typ.
0.00
0.20
0.14
0.28
1.40
1.60
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Page: 91 of 95
VBIAS
VA
V3P3A
GNDA
51
50
49
53
52
IA
IB
54
OPT_RX
57
V1
GNDA
58
VREF
XIN
59
55
TEST
60
56
VLCD
XOUT
61
E_RST
62
E_TCLK
1
63
GNDD
64
Pinout (Top View)
48
RESETZ
E_RXTX
2
47
V2P5
OPT_TX
3
46
VBAT
TMUXOUT
4
45
RX
TX
5
44
SEG31/DIO11
SEG3/SCLK
6
43
SEG30/DIO10
42
SEG29/DIO9
41
SEG28/DIO8
40
SEG27/DIO7
VDRV
7
CKTEST
8
V3P3D
9
TERIDIAN
71M6511-IGT
30
31
SEG13
SEG14
SEG15
29
SEG12
32
28
SEG11
SEG9
SEG10
27
26
SEG16
25
SEG17
33
SEG8
34
16
SEG7/MUX_SYNC
COM2
COM3
24
SEG18
23
35
22
14
15
SEG6/SRDY
COM1
SEG36/DIO16
SEG19
21
36
SEG35/DIO15
13
20
SEG24/DIO4
COM0
19
37
SEG2
12
SEG34/DIO14
SEG25/DIO5
SEG37/DIO17
18
SEG26/DIO6
38
17
39
11
SEG1
10
SEG5/SFR
SEG0
SEG4/SSDATA
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Pin Descriptions
Power/Ground Pins
Name
Pin #
Type
Description
GNDA
49, 58
P
Analog ground: This pin should be connected directly to the ground plane.
GNDD
1
P
Digital ground: This pin should be connected directly to the ground plane.
V3P3A
50
P
Analog power supply: A 3.3V power supply should be connected to this pin.
V3P3D
9
P
VBAT
46
P
V2P5
47
O
Digital power supply: A 3.3V power supply should be connected to this pin.
Battery backup power supply. A battery or super-capacitor should be connected between VBAT
and GNDD. If no battery is used, connect VBAT to V3P3D.
Output of the internal 2.5V regulator. A 0.1µF capacitor to GNDA should be connected to this
pin.
VLCD
62
P
LCD power supply. A DC source of 3.3V to 5.0V should be connected to this pin.
Analog Pins
Name
Pin #
Type
Circuit
IA
54
I
6
VA
51
I
6
IB
53
I
6
V1
56
I
7
VREF
55
O
9
VBIAS
52
O
9
XIN
XOUT
59
61
I
8
VDRV
7
O
4
Description
Line Current Sense Input: This pin is a voltage input to the internal A/D converter.
Typically, it is connected to the output of a current transformer or shunt resistor. If
the pin is unused it must be connected to V3P3A or tied to the IB pin.
Line Voltage Sense Input: This pin is a voltage input to the internal A/D converter.
Typically, it is connected to the output of a resistor divider. If the pin is unused it
must be tied to V3P3A.
Line Current Sense Input: This pin is a voltage input to the internal A/D converter.
Typically, it is connected to the output of a current transformer or shunt resistor. If
the pin is unused it must be connected to V3P3A or tied to the IA pin.
Comparator Input: This pin is a voltage input to the internal comparator. The voltage
applied to the pin is compared to an internal reference voltage of 1.5V. If the input
voltage is above the reference, the comparator output will be high (1). If the
comparator output is low, a voltage fault will occur. See the precautions in the
Applications Section for terminating this pin.
Voltage Reference for the ADC. A 0.1µF capacitor to GNDA should be connected to
this pin.
This pin outputs the reference voltage used by the power fault detection circuit. A
1,000pF capacitor to GND should be connected to this pin.
Crystal Inputs: A 32kHz style crystal should be connected across these pins.
Typically, a 20pF capacitor is also connected from each pin to GNDA. It is important
to minimize the capacitance between these pins. See the crystal manufacturer
datasheet for details.
Voltage boost output.
Pin types: P = Power, O = Output, I = Input, I/O = Input/Output
The circuit number denotes the equivalent circuit, as specified under “I/O Equivalent Circuits”.
Page: 92 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
Digital Pins:
Name
Type
Circuit
O
5
LCD Common Outputs: These 4 pins provide the select signals for the
LCD display.
O
5
Dedicated LCD Segment Output pins.
See
pinout
O
3, 4, 5
24
O
4, 5
SEG6/SRDY
23
I/O
2, 5
SEG5/SFR
11
O
4, 5
SEG4/SDATA
10
O
4, 5
SEG3/SCLK
6
O
4, 5
CKTEST
TMUXOUT
8
4
O
O
4
4
OPT_RX
57
I
7
OPT_TX
3
O
4
RESETZ
48
I
1
RX
45
I
3
TX
E_RXTX
E_TCLK
5
2
64
O
I/O
O
4
1, 4
4
E_RST
63
I/O
1, 4
TEST
60
I
7
COM3,
COM2,
COM1,
COM0
SEG19…SEG8,
SEG2…SEG0
SEG24/DIO4…
SEG31/DIO11,
SEG34/DIO14…
SEG37/DIO17
SEG7/
MUX_SYNC
Pin #
16
15
14
13
See
pinout
Description
Multi-use pins, configurable as either LCD SEG driver or DIO (DIO4 =
SCK, DIO5 = SDA when configured as EEPROM interface, WPULSE
= DIO6, VARPULSE = DIO7 when configured as pulse outputs). If
unused, these pins must be configured as outputs.
Multi-use-pin LCD Segment Output/ MUX_SYNC is output for
Synchronous serial interface
Multi-use-pin, LCD Segment Outputs/ SRDY input for Synchronous
serial interface. When configured as SRDY, this pin must be pulled
down to GNDD.
Multi-use-pin, LCD Segment Output/ SFR output for Synchronous
serial interface.
Multi-use-pin, LCD Segment Output/ SDATA output for Synchronous
serial interface.
Multi-use-pin, LCD Segment Output/ SCLK output for Synchronous
serial interface.
Clock PLL output. Can be enabled and disabled by CKOUT_DIS.
Digital output test multiplexer. Controlled by DMUX[3:0].
Optical Receive Input: This pin may receive a signal from an external
photo-detector used in an IR serial interface. If this pin is unused it
must be terminated to V3P3D or GNDD.
Optical LED Transmit Output: This pin is designed to directly drive an
LED for transmitting data in an IR serial interface. Can be tristated with
OPT_TXDIS to be multiplexed with other DIO pins.
This input pin resets the chip into a known state. For normal operation,
this pin is set to 1. To reset the chip, this pin is driven to 0. This pin
has an internal 30µA (nominal) current source pull up. A 0.1µF capacitor to GNDD should be connected to this pin. See the precautions in the Applications Section for terminating this pin.
UART input. The voltage applied at this input must be below 3.6V.
If this pin is unused it must be terminated to V3P3D or GNDD.
UART output.
Emulator serial data. This pin has an internal pull-up resistor.
Emulator clock.
Emulator reset. This pin has an internal pull-up resistor. See the
precautions in the Applications Section for terminating this pin.
Enables Production Test. This pin must be grounded in normal
operation.
Pin types: P = Power, O = Output, I = Input, I/O = Input/Output
The circuit number denotes the equivalent circuit, as specified on the following page.
Page: 93 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
I/O Equivalent Circuits:
V3P3D
V3P3D
V3P3A
110K
Digital
Input
Pin
CMOS
Input
LCD SEG
Output
Pin
LCD
Driver
from
internal
reference
VREF
Pin
GNDD
GNDD
Digital Input Equivalent Circuit
Type 1:
Standard Digital Input or
pin configured as DIO Input
with Internal Pull-Up
GNDA
LCD Output Equivalent Circuit
Type 5:
LCD SEG or
pin configured as LCD SEG
VREF Equivalent Circuit
Type 9:
VREF
V3P3D
V3P3A
V3P3D
Digital
Input
Pin
CMOS
Input
110K
GNDD
GNDD
Analog
Input
Pin
To
MUX
from
internal
reference
V2P5
Pin
GNDD
GNDA
Digital Input
Type 2:
Pin configured as DIO Input
with Internal Pull-Down
V2P5 Equivalent Circuit
Type 10:
V2P5
Analog Input Equivalent Circuit
Type 6:
ADC Input
V3P3D
V3P3A
Digital
Input
Pin
CMOS
Input
Comparator
Input
Pin
To
Comparator
LCD
Drivers
VLCD
Pin
GNDD
GNDA
Digital Input Type 3:
Standard Digital Input or
pin configured as DIO Input
GNDD
Comparator Input Equivalent
Circuit Type 7:
Comparator Input
VLCD Equivalent Circuit
Type 11:
VLCD Power
V3P3D
V3P3D
V3P3D
Digital
Output
Pin
CMOS
Output
Oscillator
Pin
To
Oscillator
Power
Down
Circuits
VBAT
Pin
GNDD
GNDD
Digital Output Equivalent Circuit
Type 4:
Standard Digital Output or
pin configured as DIO Output
Page: 94 of 95
GNDD
Oscillator Equivalent Circuit
Type 8:
Oscillator I/O
GNDD
VBAT Equivalent Circuit
Type 12:
VBAT Power
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6
71M6511/71M6511H
Single-Phase Energy Meter IC
DATA SHEET
AUGUST 2007
ORDERING INFORMATION
ORDERING
NUMBER
PACKAGE
MARKING
71M6511-IGT
71M6511-IGT
71M6511
64-pin Lead-Free LQFP, 0.5% accuracy
71M6511-IGT/F
71M6511-IGT
71M6511
64-pin LQFP, 0.5% accuracy, T&R
71M6511-IGTR
71M6511-IGT
71M6511-IGTR/F
71M6511-IGT
71M6511H-IGT
71M6511H-IGT
71M6511H
64-pin Lead-Free LQFP, 0.1% accuracy
71M6511H-IGT/F
71M6511H-IGT
71M6511H
64-pin LQFP, 0.1% accuracy, T&R
71M6511H-IGTR
71M6511H-IGT
71M6511H-IGTR/F
71M6511H-IGT
PART DESCRIPTION
71M6511
64-pin LQFP, 0.5% accuracy
71M6511
64-pin Lead-Free LQFP, 0.5% accuracy, T&R
71M6511H
64-pin LQFP, 0.1% accuracy
71M6511H
64-pin Lead-Free LQFP, 0.1% accuracy, T&R
Data Sheet: This Data Sheet is proprietary to TERIDIAN Semiconductor Corporation (TSC) and sets forth design goals for the described
product. The data sheet is subject to change. TSC assumes no obligation regarding future manufacture, unless agreed to in writing. If and
when manufactured and sold, this product is sold subject to the terms and conditions of sale supplied at the time of order acknowledgment,
including those pertaining to warranty, patent infringement and limitation of liability. TERIDIAN Semiconductor Corporation (TSC) reserves
the right to make changes in specifications at any time without notice. Accordingly, the reader is cautioned to verify that a data sheet is
current before placing orders. TSC assumes no liability for applications assistance.
TERIDIAN Semiconductor Corp., 6440 Oak Canyon, Irvine, CA 92618
TEL (714) 508-8800, FAX (714) 508-8877, http://www.teridian.com
8/17/2007
Page: 95 of 95
© 2005-2007 TERIDIAN Semiconductor Corporation
V2.6