IRF IRMCK203

Data Sheet No. PD60225 revA
IRMCK203
High Performance Sensorless Motion Control IC
Features
Product Summary
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Max Clock input
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Complete Sensorless control IC for Permanent
Magnet AC motors
No phase voltage feedback sensing required
Sinusoidal current waveform with Synchronously
Rotating Frame closed loop current control
High starting torque and smooth speed ramping
Direct interface to IR2175 current sensing high
voltage IC
Auto Retry at startup with configurable starting
torque
Versatile loss minimization Space Vector PWM
Serial communication interface (RS232C, RS422,
SPI)
2
I C serial interface to 1k bit serial EEPROM for
parameter storage for stand alone operation
Phase loss/Overcurrent/Overvoltage protection
7-bit discrete I/O for sequencing and status
monitor
Integrated brake IGBT control for dc bus voltage
limitation
TM
ServoDesigner
tool for easy operation
Parallel interface for microcontroller expansion
Sensorless control computation time
Speed operating range (typical)
33.3 MHz
10 µsec max
5% to 100%
Speed control resolution
15 bit full range
Adjustable current limit at start-up
15 bit full range
Programmable retry on start-up
max 16 trials
Over current, speed, phase loss, dc bus fault protection
PWM carrier frequency
16 bit/33MHz
IR2175 Current feedback data resolution
10bit
Inverter leg current sensing (optional)
12bit
RS232C speed
Optional RS422 communication
Max SPI Clock
up to 57.6 Kbps
up to 1 Mbps
8 MHz
Package: QFP80
Description
IRMCK203 is a high performance digital motion control IC for Sensorless AC permanent magnet motor application. Control is
based on closed loop vector control for sinusoidal Back EMF motors. With IRMCK203, the users can readily build a high
performance Sensorless drive system without any programming effort and minimum start-up time. Built-in unique start-up and
ramping algorithm enables wide application. This IC is versatile enough that the users can configure and optimize system
performance according to the needs of each application. With International Rectifier iMOTION products including high voltage
ICs such as IR2175 current sensing IC and IRAM series of Intelligent IGBT module in combination with IRMCK203, the end
result is a fully optimized system with reduced electronics component counts. This simplifies the design for low cost Sensorless
drive modules. IRMCK203 can be easily adapted to various permanent magnet motors through ServoDesignerTM tool, which is
the fully configurable graphic user interface tool.
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
IRMCK203
Overview
IRMCK203 is a new International Rectifier integrated circuit device designed for one-chip solution for complete
closed loop current and velocity control of a high performance Sensorless drive for PM motors. Unlike a traditional
microcontroller or DSP, IRMCK203 does not require any programming to complete complex Sensorless algorithm
development. Combined with International Rectifier's high voltage gate drive and current sensing IC, the user can
implement complete speed control of PM motors with minimum component count and virtually no design effort. In
addition to Sensorless closed loop speed control operation, features such as Start-up retry, Phase Loss detection,
Low Loss PWM, Regeneration Braking control and various drive protections are all implemented inside
IRMCK203. Analog and digital I/Os can also be configured. Host communication logic contains Asynchronous
Communication Interface for RS232C or RS422 communication interface, a fast slave SPI interface and an 8 bit
wide Host Parallel Interface. All communication ports have the same access capability to the host register set. The
users can write to, and read from the predefined registers to configure and monitor the drive through these
communication ports.
IRMCK203 Main functions
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Complete closed loop current control based on Synchronously Rotating Frame Field Orientation (using Rotor
Angle Observer)
Closed loop velocity control based on estimated speed
Configurable parameters (PI controller gains, PI output limit range, current feedback
scaling, PWM carrier frequency) provide adaptation to various PM motors
Built-in Sensorless control logic for start-up, ramping, and running conditions
Auto Retry (programmable) on start-up with configurable torque current limit
Analog reference input (can be used for speed reference)
RS232C/RS422 reference input
Full dynamic braking control for DC bus voltage limitation
Cycle-by-cycle on/off Control for Brake IGBT
Loss minimization Space Vector PWM with deadtime insertion
Build-in two IR2175 current sensing IC interfaces
Phase Loss, Overcurrent (GATEKILL input), Overvoltage, Undervoltage, Overspeed protection
Low cost serial 12bit A/D interface with multiplexer and sample/hold circuit
Optional Inverter Leg (low side) current sensing in lieu of IR2175 IC
4 channel analog output (PWM)
Local EEPROM for startup initialization of internal data/parameters through host register interface
AT24C01A, 128X8
Versatile host communication interface
RS232C or RS422 host interface
Fast SPI slave host interface with multi-drop capability
Parallel Host interface (total 12 pins)
Multiplexed data/address bus
Address Enable
RD/WR
Discrete I/Os for Standalone mode operation
STARTSTOP (Input)
ESTOP (Input)
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IRMCK203
DIR (Input)
FLTCLR (Input)
FAULT (Output)
SYNC (Output)
REDLED (Output)
GREENLED (Output)
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3
IRMCK203
Table of Contents
Overview........................................................................................................................................................................... 2
IRMCK203 Main functions .............................................................................................................................................. 2
IRMCK203 Block Diagrams............................................................................................................................................. 7
Basic Block Diagram .................................................................................................................................................... 7
Input/Output of IRMCK203.......................................................................................................................................... 8
Application Connections............................................................................................................................................. 12
IC Crystal Clock Circuitry .......................................................................................................................................... 13
PLL Clock Circuitry.................................................................................................................................................... 14
Low Pass Filter............................................................................................................................................................ 14
Implementing the Low Pass Filter Shield ............................................................................................................... 15
Cp Rp and Cs Component Values........................................................................................................................... 15
PLL Reset.................................................................................................................................................................... 15
DC Electrical Characteristics and Operating Conditions ................................................................................................ 16
Absolute Maximum Ratings........................................................................................................................................ 16
Recommended Operating Conditions ......................................................................................................................... 16
DC Characteristics ...................................................................................................................................................... 17
Common Quiescent and Leakage Current .................................................................................................................. 17
Input Characteristics – Non Schmitt Inputs ................................................................................................................ 17
Input Characteristics – Schmitt Inputs ........................................................................................................................ 17
Output Characteristics................................................................................................................................................. 17
Output Characteristics OSC2CLK .............................................................................................................................. 18
Pin and I/O Characteristic Table ................................................................................................................................. 19
Power Consumption .................................................................................................................................................... 21
AC Electrical Characteristics and Operating Conditions ................................................................................................ 22
System Level AC Characteristics................................................................................................................................ 22
Sync Pulse to Sync Pulse Timing............................................................................................................................ 22
FAULT and REDLED Response to GATEKILL ................................................................................................... 23
Host Interface AC Characteristics............................................................................................................................... 24
SPI Timing .............................................................................................................................................................. 24
Host Parallel Timing ................................................................................................................................................... 25
Host Parallel Read Cycle......................................................................................................................................... 25
Host Parallel Write Cycle........................................................................................................................................ 26
Discrete I/O Electrical Characteristics ........................................................................................................................ 27
Motion Peripheral Electrical Characteristics............................................................................................................... 28
PWM Electrical Characteristics .............................................................................................................................. 28
IR2175 Interface ..................................................................................................................................................... 28
Analog Interface Electrical Characteristics................................................................................................................. 29
ADC Timing............................................................................................................................................................ 29
PLL Interface Electrical Characteristics...................................................................................................................... 30
Appendix A Host Register Map .................................................................................................................................. 31
Register Access ........................................................................................................................................................... 31
Host Parallel Access................................................................................................................................................ 31
SPI Register Access ................................................................................................................................................ 31
RS-232 Register Access.......................................................................................................................................... 31
Write Register Definitions .......................................................................................................................................... 36
PwmConfig Register Group (Write Registers) ....................................................................................................... 36
CurrentFeedbackConfig Register Group (Write Registers) .................................................................................... 37
SystemControl Register Group (Write Registers)................................................................................................... 38
TorqueLoopConfig Register Group (Write Registers)............................................................................................ 38
VelocityControl Register Group (Write Registers)................................................................................................. 39
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IRMCK203
FaultControl Register Group (Write Registers) ...................................................................................................... 40
SystemConfig Register Group (Write Registers).................................................................................................... 41
EepromControl Registers (Write Registers)............................................................................................................ 42
ClosedLoopAngleEstimator Registers (Write Registers)........................................................................................ 43
OpenLoopAngleEstimator Registers (Write Registers) .......................................................................................... 44
StartupAngleEstimator Registers (Write Registers)................................................................................................ 44
StartupRetrial Registers (Write Registers) .............................................................................................................. 45
PhaseLossDetect Registers (Write Registers) ......................................................................................................... 47
D/AConverter Registers (Write Registers) ............................................................................................................. 47
Factory Test Register (Write Register) ................................................................................................................... 48
Read Register Definitions ........................................................................................................................................... 49
SystemStatus Register Group (Read Registers) ...................................................................................................... 49
DcBusVoltage Register Group (Read Registers) .................................................................................................... 49
FocDiagnosticData Register Group (Read Registers)............................................................................................. 50
FaultStatus Register Group (Read Registers).......................................................................................................... 51
VelocityStatus Register Group (Read Registers) .................................................................................................... 52
CurrentFeedbackOffset Register Group (Read Registers) ...................................................................................... 53
EepromStatus Registers (Read Registers)............................................................................................................... 53
FOCDiagnosticDataSupplement Register Group (Read Registers) ........................................................................ 54
ProductIdentification Registers (Read Registers) ................................................................................................... 55
Factory Register (Read Register) ............................................................................................................................ 55
Appendix B Package ................................................................................................................................................... 56
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IRMCK203
Table of Figures
Figure 1: IRMCS2031 Simplified Blocks......................................................................................................................... 7
Figure 2: Input/Output of IRMCK203 .............................................................................................................................. 8
Figure 3: Application Connection of IRMCK203........................................................................................................... 12
Figure 4: Oscillator Circuit ............................................................................................................................................. 13
Figure 5: PLL Low Pass Filter Shielding........................................................................................................................ 14
Figure 6: System Level SYNC To SYNC Timing .......................................................................................................... 22
Figure 7: FAULT and REDLED Response to GATEKILL............................................................................................ 23
Figure 8: SPI Timing....................................................................................................................................................... 24
Figure 9: Host Parallel Read Cycle ................................................................................................................................. 25
Figure 10: Host Parallel Write Cycle .............................................................................................................................. 26
Figure 11: Discrete I/O Timing....................................................................................................................................... 27
Figure 12: PWM Timing................................................................................................................................................. 28
Figure 13: IR2175 Interface............................................................................................................................................ 28
Figure 14: Top Level ADC Timing ................................................................................................................................ 29
Table of Tables
Table 1: Typical Values for the Clock Circuit ................................................................................................................ 13
Table 2: PLL Test Pin Assignments................................................................................................................................ 14
Table 3: PLL Low Pass Filter Values ............................................................................................................................. 15
Table 4: Absolute Maximum Ratings ............................................................................................................................. 16
Table 5: Recommended Operating Conditions ............................................................................................................... 16
Table 6: DC Characteristics ............................................................................................................................................ 17
Table 7: Non Schmitt Input Characteristics .................................................................................................................... 17
Table 8: Schmitt Input Characteristics ............................................................................................................................ 17
Table 9: Output Characteristics....................................................................................................................................... 17
Table 10: Output Characteristics OSC2CLK .................................................................................................................. 18
Table 11: Pin and I/O Characteristics ............................................................................................................................. 21
Table 12: IRMCK203 Power Consumption.................................................................................................................... 21
Table 13: System Level SYNC to SYNC Timing........................................................................................................... 22
Table 14: FAULT and REDLED Response to GATEKILL ........................................................................................... 23
Table 15: SPI Timing ...................................................................................................................................................... 24
Table 16: Host Parallel Read Cycle Timing.................................................................................................................... 25
Table 17: Host Parallel Write Cycle Timing................................................................................................................... 26
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
6
IRMCK203
IRMCK203 Block Diagrams
Basic Block Diagram
Figure 1 shows the basic block diagram of the IRMCK203 surrounded by International Rectifiers’ ICs. Host
communications are provided over SPI, RS-232C or Host parallel ports. Two current sensing ICs (IR2175) and a
three phase high voltage gate drive typically implement the high voltage / current interface between the IRMCK203 IC
and motor.
The IRMCK203 can operate in a “stand-alone” mode without the host controller.
utilized to load motor-specific parameters into the IC.
A serial EEPROM would be
AC Power
Analog
Monitor
IRMCS2031
EEPROM
Analog Speed
Reference
IRMCK203
select
A/D
interface
4
channel
D/A
Host
Controller
SPI
Interface
Parallel
Interface
RAMP
+
+
Host
Register
Interface
jθ
-
-
e
+
Space
Vector
PWM
FAULT
Monitoring
Registers
e
2/3
DC bus feedback
Plug-N-DriveTM
IGBT module
IRAMY20UP60A
Rotor Angle/
speed
Estimator
jθ
MUX
Dead
time
-
Configuration
Registers
A/D
BRAKE
IR2136
RS232C
or
RS422
DC bus dynamic
brake control
Period/Duty
counters
IR2175
Period/Duty
counters
IR2175
Motor
Figure 1: IRMCS2031 Simplified Blocks
Configurable parameters are provided to tailor design to various applications (motor and load). These configurable
parameters can be modified via the host register interface through the communication interface. In the IRMCK203
product, a design spread sheet is provided to aid the user for ease of drive start-up, the spread sheet will input high
level application data such as motor name plate information, max speed, current limit, speed and current regulator
bandwidth, base on this information the program will generate the required configurable parameters. Detail on Drive
commissioning is described in the IRMCK203 Application Developer’s Guide.
All logic and algorithms are pre-programmed, and the user does not need to make any effort to develop code,
alleviating the tedious design process. If needed, the user can configure the drive to tailor the control per specific
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IRMCK203
needs to meet the required specification. This configuration can be easily done by accessing the host register
interface through the communication interface.
Input/Output of IRMCK203
The I/O signals are shown in Figure 2. The interface signals are divided into sub-groups.
assignment, please refer to appendix (Pin definition).
For detailed pin
OSC1CLK
Crystal
OSC2CLK
PWMUH
BYPASSMODE
PWMUL
PWMVH
PLLTEST
XPD
PWMVL
PWMWH
CHGO
PWMWL
AVDD
LPVSS
BRAKE
FLTCLROUT
VSSHC
GATEKILL
PLL
Clock
Control
SPI
Interface
SPICLK
SPIMISO
IFB[0-1]
SPIMOSI
SPICSN
DAC[0-3]
RS232C
Interface
Parallel
Interface
TX
RX
BAUDSEL
IRMCK203
PWM gate signal
Interface
IR2175 Interface
D/A Interface
(PWM output)
ADCLK
ADOUT
ADCONVST
HPD[0-7]
HPOEN
ADMUX[0-2]
HPWEN
HPCSN
RESSAMPLE
A/D Interface
HPA
Discrete I/O
STARTSTOP
ESTOP
FLTCLR
SYNC
FAULT
DIR
RESETN
Serial EEPROM
System Reset
SCA
SCL
LED/Status
REDLED
GREENLED
Figure 2: Input/Output of IRMCK203
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IRMCK203
Host Interface Group
SPICLK
I
SPIMISO
SPIMOSI
SPICSN
HPOEN
O
I
I
I
Low (L) /
High (H) True
Asserted
Positive edge
sensitive
L
L
HPWEN
I
L
I/O
-
HPA
I
H
HPCSN
TX
RX
I
O
I
L
-
BAUDSEL[1:0]
I
H
SYNC
O
L
CLK1XOUT
O
-
Signal
HPD [7:0]
Input (I) /
Output (O)
Function
SPI clock
Master input and slave output
Master output and slave input
SPI chip select
Parallel data output enable
Parallel data write cycle
identification
Parallel data
Parallel data address cycle
identification
Chip select
RS-232 data out
RS-232 data in
RS-232 baud rate:
00 = 19.3K bps;
01 = 38.4K bps
10 = 57.6K bps;
11 = 1.031250M bps
Start of PWM cycle
33.333 MHz output of PLL. This
signal has no phase relationship
with the OSC1CLK or OSC2CLK
inputs.
Discrete I/O Group
Input (I) /
Output (O)
Low (L) /
High (H) True
Asserted
STARTSTOP
I
H
DIR
I
H
FAULTCLR
I
H
ESTOP
I
H
PWEN
SYNC
FAULT
O
O
O
H
H
H
Signal
Function
Start / Stop command edge
sensitive
Forward/Reverse Direction
command, level sensitive
Fault Clear
Emergency Stop, state
sensitive
PWM enable/disable state
SYNC pulse
Fault state
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IRMCK203
Motion Peripheral Group
Signal
Input (I) /
Output (O)
PWMUH
PWMUL
PWMVH
PWHVL
PWMWH
PWMWL
BRAKE
O
O
O
O
O
O
O
GATEKILL
I
IFB0
IFB1
I
I
Low (L) /
High (H) True
Asserted
-
L
Varies, Based on
Write Register
0x0C Bit 7
-
Function
PWM phase U high side
PWM phase U low side
PWM phase V high side
PWM phase V low side
PWM phase W high side
PWM phase W low side
IGBT gate
When asserted, negates all six
PWM signals, host writeable
Channel 0 (phase V)
Channel 1 (phase W)
Analog Interface Group
Signal
Input (I) /
Output (O)
ADCLK
O
ADOUT
DAC [3:0]
ADCONVST
I
O
O
RESSAMPLE
O
ADMUX0
ADMUX1
O
O
Low (L) /
High (H) True
Asserted
Negative Edge
Sensitive
L
H
H
Function
Clock to ADS7818
Serial data from ADS7818
Diagnostic DAC
Conversion start to ADS7818
Sample/hold control signal
channel 0 A/D converter
Analog input MUX select
Analog input MUX select
PLL Interface Group
XPD
RESETN
I
I
Low (L) /
High (H) True
Asserted
L
L
BYPASSCLK
I
H
BYPASSMODE
I
H
OSC1CLK
OSC2CLK
I
I
-
PLLTEST
I
H
I/O
I/O
-
Signal
CHGO
LPVSS
Input (I) /
Output (O)
Function
PLL reset
Digital logic reset
Internal test pin – force to logic
low
Internal test pin – force to logic
low
33.33 MHz crystal input
33.33 MHz crystal input
Internal test pin – force to logic
low
Low pass filter
Low pass filter ground
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IRMCK203
Miscellaneous Group
Signal
Input (I) /
Output (O)
SCA
I/O
SCL
O
GREENLED
REDLED
O
O
Low (L) /
High (H) True
Asserted
Positive Edge
Sensitive
H
H
Function
EEPROM data
EEPROM clock
LED signal
LED signal
Power Supply Group
Signal
LVDD
AVCC
MVDD
VSSHC
Function
IC Logic +3.3V power supply
IC Analog +3.3V power supply
IC Phase +3.3V Lock Loop power supply
IC Phase Lock Loop power supply return
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11
IRMCK203
Application Connections
Typical application connection is shown in Figure 3. In order to complete a Sensorless drive control, all necessary
components are shown in connection to IRMCK203.
Although this is a typical hardware configuration, users can customize the design without the effort of modifying code.
OSC1CLK
33MHz
Crystal
System
Clock
OSC2CLK
SPI Interface
TX
RX
MAX232A
To PC
PWMUH
PWMUL
PWMVH
PWMVL
PWMWH
PWMWL
BRAKE
SPICLK
SPIMISO
SPIMOSI
SPICSN
Gate Drive
&
IGBTs
GATEKILL
FAULTCLR
BAUDSEL[1:0]
Optional
microcontroller
8051
uP
HPD[0-7]
HPOEN,HPWEN
DIR
ESTOP
FLTCLR
SYNC
FAULT
LED
Serial EEPROM
Bi-Color
LED
AT24C01A
SCA
SCL
IRMCK203
Digital Control
IC
PO
Isolator
STARTSTOP
Discrete
I/O
switches
Motor Phase
Shunt
5V
IFB0
HPCSN,HPA
IR2175
IFB1
Isolator
Motor Current
Sensing
Motor Phase
Shunt
5V
PO
IR2175
Analog Speed
Reference
ADCLK
ADOUT
ADCONVST
DC bus voltage
ADS7818
4051
REDLED
GREENLED
ADMUX0
2-leg shunt
current
sensing
(optional)
ADMUX1
ADMUX2
RESSAMPLE
DAC0
DAC1
Analog Output
DAC2
DAC3
CHGO
BYPASSCLK
BYPASSMODE
PLLTEST
PLL Low Pass
FIlter
LPVSS
Figure 3: Application Connection of IRMCK203
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12
IRMCK203
IC Crystal Clock Circuitry
The clock input to the IC is a 33.33 MHz crystal oscillator.
required to terminate the crystal to the IC.
Two shunt capacitors and a possibly a series resistor is
The values of the R/C will vary based on actual PCB attributes, and some empirical analysis may be required to get the
PLL to start oscillating. Once oscillating, verify that the signal waveform at the OSC1CLK and OSC2CLK pins are
sinusoidal rather than trapezoidal. Refer to Table 1 for suggested R/C values. Most low-cost crystals can be used
in this application. An example is a Citizen Part number CM309B33.333MABJT available from Digi-Key under
part number 300-4160-1-ND.
OSC1CLK
IRMCK203
C1
XTAL
R2
OSC2CLK
R1
C2
Figure 4: Oscillator Circuit
Component
XTAL
C1
C2
R1
R2
Value
33.33
5
5
0
3.9K
Units
MHz
pF
pF
Ω
Ω
Table 1: Typical Values for the Clock Circuit
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IRMCK203
PLL Clock Circuitry
The IRMCK203 contains a PLL that creates a 2X and 4X clock from the input 33.33 MHz input clock pin.
are a number of pins on the IC allocated for factory testing purposes that need to be connected to VSS.
Table 2 shows required PCB signal connections for these pins.
Pin Number
1
7
There
PCB Connection
VSS
VSS
Table 2: PLL Test Pin Assignments
Low Pass Filter
The low pass filter for this PLL resides between the CHGO and LPVSS pins.
required to implement this filter: Cp, Rp and Cs.
Three passive components are
Figure 5 shows how to place these components around the IC.
A shield should be placed below Rp, Cp and Cs made out of copper etch.
S h ie ld e d b y L P V S S
CHGO
Rp
IR M C K 2 0 3
Cs
Cp
LPVSS
Figure 5: PLL Low Pass Filter Shielding
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14
IRMCK203
Implementing the Low Pass Filter Shield
Make all connections between CHGO, Rp, Cp, Cs and LPVSS as short as possible. Create the underlining shield by
“copper filling” a larger area in the signal plane of the PCB. Connect this shield to the LPVSS pin of the IC. Do
not connect this shield to signal ground (VSS).
Cp Rp and Cs Component Values
For a typical FR4 PCB, the values of the passive components are shown in Table 3.
Component
Rp
Cp
Cs
Value
3.9K
1000
Not Installed
Units
Ω
pF
-
Table 3: PLL Low Pass Filter Values
PLL Reset
There are two reset pins on the IC, XPD and RESETN both low true. XPD holds the PLL circuitry in reset when
low. Upon XPD going high, the PLL circuitry begins to lock onto the 33.33 MHz clock input. The PLL circuit
may take up to 1 msec to become stable. RESETN asserted low holds the internal DSP logic in reset. Upon
RESETN going high, the IC digital logic becomes active.
RESET should be held low during and at least 1 ms after XPD goes high false to hold the internal logic in reset while
the PLL becomes stable.
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15
IRMCK203
DC Electrical Characteristics and Operating Conditions
Absolute Maximum Ratings
Note: VSS = 0 Volt
PARAMETER
SYMBOL
LIMITS
NOTE
VSS-0.3 to 4.0
UNIT
S
V
Power Supply
Voltage
Input Voltage
VDD
VI
VSS-0.3 to VDD+0.5
V
Input Voltage
VI
VSS-0.3 to 7
V
Non 5 Volt
Tolerant Pins
(Table 11)
Only on 5 Volt
Tolerant Pins
(Table 11)
Output Voltage
Output Current
per Pin
Storage
Temperature
VO
IOUT
VSS-0.3 to VDD+0.5
+/- 30
V
mA
Tstg
-65 to 150
°C
Table 4: Absolute Maximum Ratings
Recommended Operating Conditions
Note: VSS = 0 Volt
PARAMETER
Power Supply
Voltage
Input Voltage
SYMBOL
VDD
MIN
3.0
TYP
3.3
MAX
3.6
UNITS
V
NOTE
VI
VSS
-
VDD
V
Input Voltage
VI
VSS
-
5.5
V
Ambient
Temperature
Ta
-40
-
85
Non 5 Volt Tolerant Pins
(Table 11)
Only on 5 Volt Tolerant
Pins (Table 11)
Note 2
°C
Table 5: Recommended Operating Conditions
Notes:
2. The ambient temperature range is recommended for Tj= -40 to 125 °C
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16
IRMCK203
DC Characteristics
Common Quiescent and Leakage Current
PARAMETER
Quiescent
Current
SYMBOL
IDDS
Input Leakage
Current
ILI
CONDITIONS
VI=VDD or VSS
VDD=MAX
IOH=IOL=0
Ta=Tj=85°C
VDD=MAX
VIH=VDD
VIL=VSS
MIN
-
TYP
-
MAX
.35
UNITS
uA
-1
-
1
uA
Table 6: DC Characteristics
Input Characteristics – Non Schmitt Inputs
PARAMETER
High Level
Input Voltage
Low Level
Input Voltage
SYMBOL
VIH1
CONDITIONS
VDD=MAX
MIN
2.0
TYP
-
MAX
-
UNITS
V
VIL1
VDD=MIN
-
-
0.8
V
Table 7: Non Schmitt Input Characteristics
Input Characteristics – Schmitt Inputs
PARAMETER
High Level
Input Voltage
Low Level
Input Voltage
Hysteresis
Voltage
SYMBOL
VT1+
CONDITIONS
VDD=MAX
MIN
1.1
TYP
-
MAX
2.4
UNITS
V
VT1-
VDD=MIN
0.6
-
1.8
V
VH1
VDD=MIN
0.1
-
-
V
Table 8: Schmitt Input Characteristics
Output Characteristics
PARAMETER
High Level
Output Voltage
Low Level
Output Voltage
SYMBOL
VOH3
VOL3
CONDITIONS
VDD=MIN
IOH=-12mA
VDD=MIN
IOH = 12mA
MIN
VDD - 0.4
TYP
-
MAX
-
UNITS
V
-
-
VSS + 0.4
V
Table 9: Output Characteristics
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
17
IRMCK203
Output Characteristics OSC2CLK
PARAMETER
High Level
Output Voltage
Low Level
Output Voltage
SYMBOL
LVOH
LVOL
CONDITIONS
VDD=MIN
IOH=-530uA
VDD=MIN
IOH = 730uA
MIN
VDD - 0.4
TYP
-
MAX
-
UNITS
V
-
-
VSS + 0.4
V
Table 10: Output Characteristics OSC2CLK
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
18
IRMCK203
Pin and I/O Characteristic Table
Pin
Number
Pin Name
1
BYPASSMODE
2
3
4
5
6
7
FLTCLROUT
OSC1CLK
LVDD
OSC2CLK
VSS
PLLTEST
8
9
10
11
12
13
14
15
XPD
VSSHC
MVDD
VSSHC
AVDD
CHGO
LPVSS
DIR
16
RESETN
17
18
19
20
21
22
23
24
25
26
27
28
29
30
SPICSN
REDLED
GREENLED
VSS
PWMWL
PWMWH
PWMVL
LVDD
PWMVH
PWMUL
VSS
PWMUH
BRAKE
BAUDSEL0
31
GATEKILL
32
33
34
35
36
37
38
39
40
IFB1
IFB2
LVDD
CLK1XOUT
VSS
SPIMOSI
SPIMISO
SPICLK
TX
INTERNAL IC
RESISTOR
TERMINATION
40K-240K Pull
Down
20K-120K Pull
Down
20K – 120K
Pull Down
20K -120K Pull
Up
20K – 120K
Pull Down
20K -120K Pull
Up
Pin
Type
I
5.50 VOLT
TOLERANT
INPUT
-
INPUT DC
CHARACTERISTIC
TABLE
Table 8
OUTPUT DC
CHARACTERISTIC
TABLE
-
O
I
P
O
P
I
-
Table 7
-
Table 9
Table 7
Table 10
-
I
P
P
P
P
O
P
I
YES
Table 7
Table 8
-
I
-
Table 8
-
I
O
O
P
O
O
O
P
O
O
P
O
O
I
YES
Table 8
Table 8
Table 9
Table 9
Table 9
Table 9
Table 9
Table 9
Table 9
Table 9
Table 9
I
-
Table 8
-
I
I
P
O
P
I
O
I
O
YES
YES
YES
YES
-
Table 8
Table 8
-
Table 9
Table 8
Table 8
-
Table 9
Table 9
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
19
IRMCK203
Pin
Number
Pin Name
41
42
RX
BAUDSEL1
43
44
45
46
47
48
49
50
51
52
53
54
LVDD
ADMUX0
VSS
ADMUX1
ADMUX2
RESSAMPLE
ADCONVST
ADCLK
ADOUT
SYNC
FAULT
STARTSTOP
55
ESTOP
56
FLTCLR
57
58
59
60
61
62
63
64
LVDD
PWMEN
DAC3
VSS
DAC2
DAC1
DAC0
HPD0
65
HPD1
66
HPD2
67
68
VDD
HPD3
69
HPD4
70
71
VSS
HPD5
72
HPD6
73
HPD7
74
75
76
77
HPOEN
HPWEN
HPA
HPCSN
INTERNAL IC
RESISTOR
TERMINATION
20K -120K Pull
Up
20K -120K Pull
Down
20K -120K Pull
Down
20K -120K Pull
Down
20K -120K Pull
Down
20K -120K Pull
Down
20K -120K Pull
Down
20K -120K Pull
Down
20K -120K Pull
Down
20K -120K Pull
Down
20K -120K Pull
Down
20K -120K Pull
Down
Pin
Type
I
I
5.50 VOLT
TOLERANT
INPUT
YES
YES
INPUT DC
CHARACTERISTIC
TABLE
Table 8
Table 8
OUTPUT DC
CHARACTERISTIC
TABLE
-
P
O
P
O
O
O
O
O
I
O
O
I
YES
YES
Table 8
Table 8
Table 9
Table 9
Table 9
Table 9
Table 9
Table 9
Table 9
Table 9
-
I
YES
Table 8
-
I
YES
Table 8
-
P
O
O
P
O
O
O
B
-
Table 7
Table 9
Table 9
Table 9
Table 9
Table 9
Table 9
B
-
Table 7
Table 9
B
-
Table 7
Table 9
P
B
-
Table 7
Table 9
B
-
Table 7
Table 9
P
B
-
Table 7
Table 9
B
-
Table 7
Table 9
B
-
Table 7
Table 9
I
I
I
I
YES
YES
YES
YES
Table 8
Table 8
Table 8
Table 8
-
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
-
20
IRMCK203
Pin
Number
78
79
80
Pin Name
VSS
SCL
SDA
INTERNAL IC
RESISTOR
TERMINATION
20K -120K Pull
Up
Pin
Type
P
O
B
5.50 VOLT
TOLERANT
INPUT
-
INPUT DC
CHARACTERISTIC
TABLE
Table 7
OUTPUT DC
CHARACTERISTIC
TABLE
Table 9
Table 9
Table 11: Pin and I/O Characteristics
Power Consumption
PARAMETER
PTotal
SYMBOL
PTOTAL
CONDITIONS
VDD=3.3V
MIN
-
TYP
1.2
MAX
-
UNITS
WATT
Table 12: IRMCK203 Power Consumption
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
21
IRMCK203
AC Electrical Characteristics and Operating Conditions
System Level AC Characteristics
Sync Pulse to Sync Pulse Timing
t5
SYNC
Current Feedback
sampling
Angle Estimation
t1
t2
t3
Closed loop current control
t4
Space Vector PWM
Figure 6: System Level SYNC To SYNC Timing
SYMBOL
t1
t2
t3
t4
t5
DESCRIPTION
Current Feedback Sample Delay
Using IR2175 for current feedback
Using Leg Shunts for current feedback (optional)
Rotor Angle Estimation Time
Current and velocity control
Space Vector PWM calculation time
Total SYNC to SYNC minimum time
TIME (µsec)
4.3
2.0
4.9
3.1
2.3
14.6 (max)
Table 13: System Level SYNC to SYNC Timing
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22
IRMCK203
FAULT and REDLED Response to GATEKILL
t5
GATEKILL
t3
t1
FAULT
t2
REDLED
t4
FLTCLR
Figure 7: FAULT and REDLED Response to GATEKILL
SYMBOL
t1
t2
t3
t4
t5
DESCRIPTION
FAULT Response to GATEKILL
REDLED Response to
GATEKILL
FAULT Response to FLTCLR
REDLED Response to FLTCLR
GATEKILL Pulse Width
MIN
TYP
640
640
UNITS
ns
ns
190
190
ns
ns
ns
485
Table 14: FAULT and REDLED Response to GATEKILL
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23
IRMCK203
Host Interface AC Characteristics
SPI Timing
tSCLK
SCLK
tCSS
CS
tMOSIS
MOSI
MISO
tMISO
tMISOZ
Figure 8: SPI Timing
SYMBOL
fSCLK
tSCLK
tCSS
tMOSIS
tMISO
tMIOZ
DESCRIPTION
SPI Clock Frequency
SPI Clock Period
CS to SCLK high Setup
MOSI to SCLK low Setup
SCLK to MISO Valid
CS to MISO High Impedance
MIN
125
20
20
73
15
MAX
8
35
UNITS
MHz
ns
ns
ns
ns
ns
Table 15: SPI Timing
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
24
IRMCK203
Host Parallel Timing
Host Parallel Read Cycle
tHPCSN
HPCSN
HPWEN
tHPWENS
HPA
tHPAS
tHPA
tAHPD
HPD[7:0]
VALID
tHPZD
tHPOENS
tHPDZ
tHPOEN
HPOEN
Figure 9: Host Parallel Read Cycle
SYMBOL
DESCRIPTION
tHPCSN
tHPWENS
tHPAS
tAHPD
THPZD
tHPDZ
tHPOENS
tHPOEN
HPCSN Period
HPWENS Setup
HPA Setup
HPD[7:0] Access
HPD[7:0] Active
HPD[7:0] High Impedance
HPOEN Setup
HPOEN Period
MIN
70
40
40
60
0
0
40
70
MAX
105
9
6
UNIT
S
ns
ns
ns
ns
ns
ns
ns
ns
NOTE
Note 3
Note 3
Table 16: Host Parallel Read Cycle Timing
Note:
3. HPOEN, HPWEN must be stable before the high to low transition of HPCSN.
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
25
IRMCK203
Host Parallel Write Cycle
tHPCSN
HPCSN
tHPWENS
tHPWEN
HPWEN
tHPAS
tHPA
tHPD[7:0]
HPD[7:0]
tHPD[7:0]S
tHPOEN
HPOEN
tHPOENS
Figure 10: Host Parallel Write Cycle
SYMBOL
tHPCSN
tHPWENS
tHPWEN
tHPAS
tHPA
tHPD[7:0]
tHPOENS
tHPOEN
DESCRIPTION
HPCSN Period
HPWENS Setup
HPWEN Period
HPA Setup
HPA Period
HPD[7:0] Setup
HPOEN Setup
HPOEN Period
MIN
70
40
70
-10
70
-10
40
70
MAX
UNITS
ns
ns
ns
ns
ns
ns
ns
ns
NOTE
Note 4
Table 17: Host Parallel Write Cycle Timing
Note:
4.
HPOEN must be asserted high while HPCSN low during a Host Parallel Write Cycle.
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
26
IRMCK203
Discrete I/O Electrical Characteristics
START/STOP
FLTCLR
tL
Figure 11: Discrete I/O Timing
SYMBOL
tL
DESCRIPTION
Pulse Width STARTSTOP
Pulse Width FLTCLR
MIN
100
1
MAX
UNITS
ns
us
Table 15: Discrete I/O Timing
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
27
IRMCK203
Motion Peripheral Electrical Characteristics
PWM Electrical Characteristics
tDEADTIMERESOLUTION
tDEADTIMERESOLUTION
SYNC
PWMUH
PWMUL
PWMVH
PWMVL
PWMWH
PWMWL
Figure 12: PWM Timing
SYMBOL
tDEADTIMERESOLUTION
DESCRIPTION
Deadtime Insertion Logic Resolution
30
UNITS
ns
Table 16: PWM Timing
IR2175 Interface
tIFB
tIFBH
IFB0
IFB1
tIFBL
Figure 13: IR2175 Interface
SYMBOL
fIFB
tIFB
tIBH
tIFBH
DESCRIPTION
Current Feedback Input Frequency
Current Feedback Period
Current Feedback High Pulse Width
Current Feedback Low Pulse Width
MIN
95
10.52
500 ns
500 ns
MAX
165
6.06
10 us
10 us
UNITS
kHz
us
Table 17: IR2175 Interface
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28
Analog Interface Electrical Characteristics
ADC Timing
System Level Timing
The IRMCK203 contains logic to drive an ADC Converter, Analog MUX and associated Sample and Hold circuits. Figure 14 shows the system level timing
of these elements. The IRMCK203 is specifically designed to interface to the Burr-Brown ADS7818 ADC. As such, all interface signals between the ADC
and IRMCK203 are guaranteed to meet worst case timing specifications over the IRMCK203 and ADS7818 specified operation environment. For interfacing
to other ADCs, please contact International Rectifier for detailed specifications. Also refer to the Application Developers Guide for a detailed description of
ADC, MUX and Sample and Hold signal system level protocol.
RESSAMPLE
ADCONVST
t2
tMUX[2:0]
t1
ADMUX0
ADMUX1
ADMUX2
ADCLK
t3
tADCLK
tCLKDLY
Figure 14: Top Level ADC Timing
SYMBOL
tMUX[2:0]
t1
t2
t3
tADCLK
tCLKDLY
DESCRIPTION
ADCONVST to MUX[2:0]
ADCONVST Low Period
ADCONVST High Period
ADCONVST to ADCLK Falling
ADCLK Period
ADCLK STALL Period
TYP
22
1.44
630
60
127.5
210
Table 18: Top Level ADC Timing
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
UNITS
ns
us
ns
ns
ns
ns
PLL Interface Electrical Characteristics
PARAMETER
Current
Consumption
Current
Consumption
Peak jitter
Cycle jitter
Lock-up Time
PLL Reset
Period
SYMBOL
IDDS
CONDITIONS
Static
MIN
-
TYP
-
MAX
170
UNITS
uA
IDD
Dynamic
-
5
-
MA
Tpj
Tcj
Tlock
Trst
Recommended
operating
condition
-500
10
-
1000
+500
1
-
ps
ps
ms
Ns
Table 20: PLL Electrical Characteristics
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
IRMCK203
Appendix A
Host Register Map
Register Access
A host computer controls the IRMCK203 using its slave-mode Full-Duplex SPI port, a standard RS-232 port or a 8-bit
parallel port for connection to a microprocessor. All interfaces are always active and can be used interchangeably,
although not simultaneously. Control/status registers are mapped into a 128-byte address space.
Host Parallel Access
The IRMCK203 contains an address register that is updated with the Host Register address when HPA = 1. After
each subsequent data byte is either read or written, the internal address register is incremented. The diagram below
shows that Data Bytes 0 to N would access register locations initially specified by the Address Byte. The Address
Byte with the HPA signal can be asserted at any time.
Address Byte
Data Byte 0
HPA = 1
HPA = 0
…………….
Data Byte N
HPA = 0
HPA = 0
Host Parallel Data Transfer Format
SPI Register Access
When configured as an SPI device read only and read/write operations are performed using the following transfer
format:
Command Byte
Data Byte 0
…………….
Data Byte N
Data Transfer Format
7
6
Read
Only
5
Bit Position
4
3
2
1
0
Register Map Starting Address
Command Byte Format
Data transfers begin at the address specified in the command byte and proceed sequentially until the SPI transfer
completes. As in the Host Parallel Access, the internal address register is incremented after each SPI byte is
transferred. Note that accesses are read/write unless the “read only” bit is set.
RS-232 Register Access
The IRMCK203 includes an RS-232 interface channel that provides a direct connection to the host PC. The software
interface combines a basic "register map" control method with a simple communication protocol to accommodate
potential communication errors.
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
31
IRMCK203
RS-232 Register Write Access
A Register write operation consists of a command/address byte, byte count, register data and checksum. When the
IRMCK203 receives the register data, it validates the checksum, writes the register data, and transmits and
acknowledgement to the host.
Command / Address Byte
Byte Count
1-6 bytes of register data
Checksum
Register Write Operation
Command Acknowledgement Byte
Checksum
Register Write Acknowledgement
7
6
5
1=Read/
0=Write
Bit Position
4
3
2
1
0
1
0
Register Map Starting Address
Command/Address Byte Format
7
1=Error/
0=OK
6
5
Bit Position
4
3
2
Register Map Starting Address
Command Acknowledgement Byte Format
The following example shows a command sequence sent from the host to the IRMCK203 requesting a two-byte
register write operation:
0x2F
Write operation beginning at offset 0x2F
0x02
Byte count of register data is 2
0x00
Data byte 1
0x04
Data byte 2
0x35
Checksum (sum of preceding bytes, overflow discarded)
A good reply from the IRMCK203 would appear as follows:
0x2F
Write completed OK at offset 0x2F
0x2F
Checksum
An error reply to the command would have the following format:
0xAF
Write at offset 0x2F completed in error
0xAF
Checksum
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
32
IRMCK203
RS-232 Register Read Access
A register read operation consists of a command/address byte, byte count and checksum. When the IRMCK203
receives the command, it validates the checksum and transmits the register data to the host.
Command / Address Byte
Byte Count
Checksum
Register Read Operation
Command Acknowledgement Byte
Register Data
(Byte Count bytes)
Checksum
Register Read Acknowledgement (transfer OK)
Command Acknowledgement Byte
Checksum
Register Read Acknowledgement (error)
The following example shows a command sequence sent from the host to the IRMCK203 requesting four bytes of read
register data:
0xA0
Read operation beginning at offset 0x20 (high-order bit selects read operation)
0x04
Requested data byte count is 4
0xA4
Checksum
A good reply from the IRMCK203 might appear as follows:
0x20
Read completed OK at offset 0x20
0x11
Data byte 1
0x22
Data byte 2
0x33
Data byte 3
0x44
Data byte 4
0xCA
Checksum
An error reply to the command would have the following format:
0xA0
Read at offset 0x20 completed in error
0xA0
Checksum
RS-232 Timeout
The IRMCK203 receiver includes a timer that automatically terminates transfers from the host to the IRMCK203 after
a period of 32 msec.
RS-232 Transfer Examples
The following example shows a normal exchange executing a register write access.
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33
IRMCK203
The example below shows a normal register read access exchange.
The following example shows a register write request that is repeated by the host due to a negative acknowledgement
from the IRMCK203.
In the final example, the host repeats a register read access request when it receives no response to its first attempt.
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
34
IRMCK203
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
35
IRMCK203
Write Register Definitions
PwmConfig Register Group (Write Registers)
Byte
Offset
7
Gatekill
Sns
(W)
0xC
5
SPARE
Gate
SnsL
(W)
Gate
SnsU
(W)
SyncSns
2
1
0
BrakeSns
SD
(W)
SPARE
PwmPeriod (LSBs)
(W)
0xD
0xE
Bit Position
4
3
6
TwoPhs
Pwm
(W)
TwoPhs
Type
(W)
PwmConfig
(W)
PwmPeriod (MSBs)
(W)
0xF
PwmDeadTm
(W)
0x44
ModScl (LSBs)
(W)
0x45
ModScl (MSBs)
(W)
0x51
PwmGuardBand
(W)
PwmConfig Write Register Map
Field
Name
SD
BrakeSns
Access
(R/W)
W
W
SyncSns
W
GateSnsU
W
GateSnsL
W
GatekillSns
W
PwmPeriod
W
PwmConfig
W
TwoPhsType
W
TwoPhsPwm
W
Field Description
Shutdown control output to IR2137.
Logic Sense for BRAKE signal output to gate driver IC. 0 = Active
low, 1 = active high.
Logic Sense for PWM SYNC signal output to microprocessor. 0 =
Active low, 1 = active high.
Upper IGBT gate sense. 1 = active high gate control, 0 = active
low gate control.
Lower IGBT gate sense. 1 = active high gate control, 0 = active
low gate control.
GATEKILL signal sense. 1 = active high GATEKILL, 0 = active low
GATEKILL.
PWM Carrier period. Actual PWM carrier period is 2 * (PwmPeriod
+ 1) * (System Clock Period).
PWM Configuration. 0 = Asymmetrical center aligned PWM, 1 =
Symmetrical Center aligned PWM.
Used only for two-phase PWM modulation mode:
0 = Type 1 2-phase PWM
1 = Type 2 2-phase PWM
Selects PWM modulation mode:
0 = Enable 3-phase space vector PWM modulation
1 = Enable 2-phase space vector PWM modulation
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
36
IRMCK203
Field
Name
PwmDeadTm
Access
(R/W)
W
Field Description
Gate drive dead time in units of system clock cycles (e.g., 30 ns
with 33 MHz clock).
Space vector modulator scale factor. This register, which
depends on the PWM carrier frequency, should be set as follows:
W
ModScl = PwmPeriod * sqrt(3) * 4096 / 2355
where PwmPeriod is the value in the PwmConfig write register
group’s PwmPeriod register.
W
This parameter provides a guard band (scaling: 1 = 30nsec) such
that PWM switching will not migrate into the current feedback
sampling instant (Sync Pulse region). This guard band is provided
to improve feedback noise. The parameter only applies to the 3phase Space Vector modulation scheme. Please do not modify
this parameter without consulting a motor drive FAE.
PwmConfig Write Register Field Definitions
ModScl
PwmGuardBand
CurrentFeedbackConfig Register Group (Write Registers)
Byte
Offset
7
6
5
Bit Position
4
3
0x15
IfbkScl (LSB)
(W)
0x16
IfbkScl (MSB)
(W)
0x7D
OffsetCalDelay
(W)
2
1
0
CurrentFeedbackConfig Write Register Map
Field
Name
IfbkScl
IfbOffsVOffse
tCal
Delay
Access
(R/W)
Field Description
Rotating frame Iq component and Id component current feedback
scale factor. Constant used to scale current measurements before
they are used in the field orientation calculation. This is a 15-bit fixedpoint signed number with 10 fractional bits that ranges from –16 to +
16 + 1023 / 1024.
This parameter specifies the delay time (1 = 1 sec) to restart current
W
offset measurement after a stop command is issued. Only applies if
Leg Shunt current feedback is selected.12-bit signed value for V
phase current feedback offset. When the IfbOffsEnb bit in the
SystemControl write register group is "0" this value is automatically
added to each current measurement in hardware.
CurrentFeedbackConfig Write Register Field Definitions
W
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
37
IRMCK203
SystemControl Register Group (Write Registers)
Byte
Offset
7
6
5
Bit Position
4
3
SPARE
0x17
2
1
0
HostEstop
StartCmd
Rotation
SystemControl Write Register Map
Field
Name
Rotation
Access
(R/W)
W
Field Description
Direction of motor rotation: 0 = Reverse motor rotation; 1 = Forward
motor rotation.
W
Start/Stop bit. Setting this bit to 1 issues a start command. Setting
this bit to 0 stops the motor.
W
Emergency coast stop will take place when this bit is set to one.
SystemControl Write Register Field Definitions
StartCmd
HostEstop
TorqueLoopConfig Register Group (Write Registers)
Byte
Offset
7
6
5
Bit Position
4
3
2
0x1A
KpIreg – Current Loop Proportional Gain (LSBs)
(W)
0x1B
KpIreg – Current Loop Proportional Gain (MSBs)
(W)
0x1C
KxIreg – Current Loop Integral Gain (LSBs)
(W)
0x1D
KxIreg – Current Loop Integral Gain (MSBs)
(W)
0x22
VqLim – Quadrature Current Output Limit (LSBs)
(W)
0x23
VqLim – Quadrature Current Output Limit (MSBs)
(W)
0x26
VdLim – Direct Current Output Limit (LSBs)
(W)
0x27
VdLim – Direct Current Output Limit (MSBs)
(W)
1
0
TorqueLoopConfig Write Register Map
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
38
IRMCK203
Field
Name
KpIreg
Access
(R/W)
W
KxIreg
W
VqLim
VdLim
W
W
Field Description
15-bit signed current loop PI controller proportional gain. Scaled with
14 fractional bits for an effective range of 0 – 1.
15-bit signed current loop PI controller integral gain. Scaled with 19
fractional bits for an effective range of 0 - .03125.
16-bit Quadrature current PI controller voltage output limit.
16-bit Direct current PI controller voltage output limit.
TorqueLoopConfig Write Register Field Definitions
VelocityControl Register Group (Write Registers)
Byte
Offset
7
6
5
Bit Position
4
3
2
0x32
KpSreg – Velocity loop proportional gain (LSBs)
(W)
0x33
KpSreg – Velocity loop proportional gain (MSBs)
(W)
0x34
KxSreg – Velocity loop integral gain (LSBs)
(W)
0x35
KxSreg – Velocity loop integral gain (MSBs)
(W)
0x36
MotorLim – Velocity loop Output Positive Limit (LSBs)
(W)
0x37
MotorLim – Velocity loop Output Positive Limit (MSBs)
(W)
0x38
RegenLim – – Velocity loop Output Negative Limit (LSBs)
0x39
RegenLim – – Velocity loop Output Negative Limit (MSBs)
0x3A
SpdScl – Speed Scale Factor (LSBs)
0x3B
SpdScl – Speed Scale Factor (MSBs)
0x3C
TargetSpd – Setpoint/target speed (LSBs)
0x3D
TargetSpd – Setpoint/target speed (MSBs)
0x3E
AccelRate
0x3F
DecelRate
0x7A
MinSpd
1
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
0
39
IRMCK203
Byte
Offset
7
6
Bit Position
4
3
5
0x18
StartLim (LSBs)
0x19
StartLim (MSBs)
2
1
0
VelocityControl Write Register Map
Field
Name
KpSreg
Access
(R/W)
W
KxSreg
W
MotorLim
W
RegenLim
W
SpdScl
W
TargetSpd
W
AccelRate
DecelRate
MinSpd
W
W
W
StartLim
W
Field Description
15-bit velocity loop proportional gain, in fixed point with 5 fractional
bits. Range = 0 - 512.
15-bit velocity loop integral gain, in fixed point with 13 fractional bits.
Range = 0 - 2.
Motoring torque current limit (4095 = rated motor current).16-bit
speed PI controller output positive limit.
Regeneration torque current limit (4095 = rated motor current)16-bit
speed PI controller output negative limit (2’s complement)..
Motor Speed Scale factor. Spd value (in the VelocityStatus read
register group) is maintained in SPEED units of SpdScl * (Encoder
counts / Velocity Loop Execution) or SpdScl * (RATE * Encoder
counts / PWM period). The user should set SpdScl = (64 * 16384) *
60 * PWMFREQ / (RATE * Max RPM * Encoder counts/revolution),
which will result in a Spd value ranging ±16384 corresponding to ±
Max RPM.
Velocity loop speed setpoint in SPEED units, which are determined
by the user via the SpdScl register setting.
Positive speedAcceleration rate limit.
Negative speedDeceleration rate limit.
Minimum speed protection. This parameter sets the minimum
reference speed.
Drive start-up current limit. (4095 = rated motor current).
VelocityControl Write Register Field Definitions
FaultControl Register Group (Write Registers)
Byte
Offset
7
0x42
6
Bit Position
4
3
5
2
1
0
FltClr
DcBusM
Enb
SPARE
FaultControl Write Register Map
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
40
IRMCK203
Field
Name
Access
(R/W)
DcBusMEnb
W
FltClr
W
Field Description
DC Bus monitor enable. 1 = Monitor DC bus voltage and generate
appropriate brake signal control and disable PWM output when
voltage fault conditions occur. GatekillFlt and OvrSpdFlt faults
cannot be disabled. DC bus voltage thresholds are as follows:
Overvoltage – 410V
Brake On – 380V
Brake Off – 360V
Nominal – 310V
Undervoltage off – 140V
Undervoltage – 120V
This bit clears all active fault conditions. The user should monitor
the FaultStatus read register group to determine fault status and set
this bit to “1” to clear any faults that have occurred. A fault condition
automatically clears the PwmEnbW and FocEnbW bits in the
SystemControl write register group. Note that this bit also directly
controls the output 2137 FLTCLR pin. After clearing a fault, the
user must explicitly set this bit to “0” to re-enable fault processing.
FaultControl Write Register Field Definitions
SystemConfig Register Group (Write Registers)
Byte
Offset
0x50
7
6
5
ExtCtrl
AdcIfbEnb
Ramp
Stop
Bit Position
4
3
2
1
0
SPARE
SystemConfig Write Register Map
Field
Name
RampStop
AdcIfbEnb
ExtCtrl
Access
(R/W)
Field Description
Selects the stopping mode:
0 - Configure for Coast stopping
1 - Configure for Ramp stopping
W
Selects the current feedback mode:
0 - Selects IR2175 current feedback
1 - Selects Leg-Shunt current feedback
Setting this bit to “1” enables direct control of basic motor operation
W
via the external User Interface pins. When this bit is “1”, the
FocEnbW and PwmEnbW bits in the SystemControl write register
group are ignored.
SystemConfig Write Register Field Definitions
W
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41
IRMCK203
EepromControl Registers (Write Registers)
At power up, the write registers can be optionally initialized with values stored in EEPROM. The EepromControl
write register group and EepromStatus read register group are used to read and write these EEPROM values. Since
the EeAddrW write register (which selects the EEPROM offset to read or write) does not require initialization at
power up, the location corresponding to that register in EEPROM (at offset 0x5D) is used to store a register map
version code. At power on, the IRMCK203 initializes the write registers from EEPROM only if the version code
stored at this offset in EEPROM matches its internal register map version code (which can be read from the
RegMapVer field of the EepromStatus read register group).
To enable write register initialization at power up, write the appropriate register map version code to EEPROM at
offset 0x5D. To disable write register initialization at power up, write a zero (or any non-matching version code) to
offset 0x5D of the EEPROM.
Byte
Offset
7
6
Bit Position
4
3
5
SPARE
0x5C
0x5D
EeAddrW / RegMapVersCode
(W)
0x5E
EeDataW
(W)
2
1
0
EeWrite
EeRead
EeRst
EepromControl Write Register Map
Field
Name
EeRst
Access
(R/W)
W
EeRead
W
EeWrite
W
EeAddrW
W
EeDataW
W
Field Description
Self-clearing EEPROM reset. Writing a "1" to this bit resets the I2C
EEPROM interface.
Self-clearing I2c EEPROM Read. Writing a "1" to this bit initiates an
EEPROM read from the byte located at EEPROM address EeAddrW.
After setting this bit the user should poll the EeBusy bit in the
EepromStatus read register group to determine when the read
completes and then read the data from EeDataR in the
EepromStatus read register group.
Self-clearing EEPROM Write. Writing a "1" to this bit initiates an
EEPROM write from the data byte in EeDataW to the EEPROM
address EeAddrW .
EEPROM Address Register. Contains the address for the next
EEPROM read or write operation.
EEPROM Data Register. Contains the data for the next EEPROM
write operation.
EepromControl Write Register Field Definitions
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42
IRMCK203
ClosedLoopAngleEstimator Registers (Write Registers)
Byte
Offset
7
6
5
Bit Position
4
3
0x60
IScl (LSBs)
(W)
0x61
IScl (MSBs
(W)
0x62
FlxBInit (LSBs)
(W)
0x63
FlxBInit (MSBs)
(W)
0x6A
PllKp (LSBs)
(W)
0x6B
SPARE
0
PllKp (MSBs
(W)
SPARE
PllKi (MSBs
(W)
0x6E
VoltScl (LSBs)
(W)
0x6F
VoltScl (MSBs
(W)
0x70
Rs (LSBs)
(W)
0x71
Rs (MSBs
(W)
0x72
Ld (LSBs)
(W)
0x73
Ld (MSBs
(W)
0x74
AtanTau (LSBs)
(W)
0x75
AtanTau (MSBs
(W)
0x76
FlxTau (LSBs)
(W)
0x77
1
PllKi (LSBs)
(W)
0x6C
0x6D
2
SPARE
FlxTau (MSBs)
(W)
ClosedLoopAngleEstimator Write Register Map
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
43
IRMCK203
Field
Name
IScl
FlxBInit
PllKp
PllKi
VoltScl
Rs
Ld
AtanTau
FlxTau
Access Field Description
(R/W)
W
Current scaler for motor flux calculation.
W
Initialization value of Beta flux at start.
W
Flux phase lock loop proportional gain.
W
Flux phase lock loop integral gain.
W
Voltage scaler for motor flux calculation.
W
Motor per phase resistance including cable (@25C).
W
Motor per phase inductance.
W
Rotor angle estimator phase compensation gain.
W
Rotor angle estimator flux model time constant.
ClosedLoopAngleEstimator Write Register Field Definitions
OpenLoopAngleEstimator Registers (Write Registers)
Byte
Offset
7
6
5
Bit Position
4
3
0x66
KTorque (LSBs)
(W)
0x67
KTorque (MSBs
(W)
0x5F
VFGain
(W)
2
1
0
OpenLoopAngleEstimator Write Register Map
Field
Name
KTorque
VFGain
Access Field Description
(R/W)
W
Motor mechanical model torque constant.
W
Open-Loop Volts/Hz Flux gain. (for diagnostic use only).
OpenLoopAngleEstimator Write Register Field Definitions
StartupAngleEstimator Registers (Write Registers)
Byte
Offset
7
6
5
0x68
2
1
0
ParkI
(W)
0x64
0x65
Bit Position
4
3
SPARE
Zero
SpdFlt
Disable
Use2xFrq
Scale
PhsLosFlt
Disable
DiagnosticCtrl
(W)
WeThr (LSBs)
(W)
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44
IRMCK203
Byte
Offset
7
6
5
Bit Position
4
3
0x69
WeThr (MSBs
(W)
0x78
ParkTm
(W)
2
1
0
StartupAngleEstimator Write Register Map
Field
Name
ParkI
DiagnosticCtrl
Access
(R/W)
W
W
Field Description
DC current injection level during motor parking (start-up mode).
1
(0001) – Enable Parking diagnostic
2
(0010) – Enable start-up diagnostic
5
(0101) – Enable current regulator diagnostic
9
(1001) – Enable volts Hertz diagnostic
W
Enable/disable phase loss fault: 0 = Enable Phase Loss Fault; 1
= Disable Phase Loss Fault
W
Selects speed scaling:
0 - Norminal speed scale
1 - Reduce speed feedback scaling by half
Please do not modify this parameter without consulting motor
control FAEs
W
Zero speed fault enable/disable:
0 - Enbale Zero Speed Fault
1 - Disable Zero Speed Fault
W
Frequency threshold level (switch over from open-loop to closedloop mode).
W
Time duration of parking mode. 255 = 4 sec
StartupAngleEstimator Write Register Field Definitions
PhsLosFlt
Disable
Use2xFrqScale
ZeroSpdFlt
Disable
WeThr
ParkTm
StartupRetrial Registers (Write Registers)
Byte
Offset
7
6
5
Bit Position
4
3
0x1E
RetryTm (LSBs)
0x1F
RetryTm (MSBs)
0x79
ParkTmRet
0x7B
FlxThrL
0x7C
FlxThrH
2
1
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0
45
IRMCK203
Byte
Offset
7
6
5
Bit Position
4
3
0x7E
NumRetries
0x7F
ParkIRet
2
1
0
StartupRetrial Write Register Map
Field
Name
Access
(R/W)
RetryTm
W
ParkTmRet
W
FlxThrL
W
FlxThrH
W
NumRetries
W
ParkIRet
W
Field Description
This parameter provides the adjustment to the sampling instant for
determination of start failure. The sampling instant starts when
Closed_Loop = 1. Scaling 1 count = 1.966 msec. Please do not
modify this parameter without consulting a motor drive FAE.
During motor start-up, dc current is injected to the motor for
maximization of startup torque per ampere rating. ParkTm controls
the duration of dc current injection. However, users are able to use a
longer duration after two or more restarts by setting this parameter
(ParkTmRet scaling 255 = 4 secs.). This is done to increase the
chance of a successful start-up.Start-up failure may be caused by
increased shaft friction. After first start-up retry, the parking time can
be increased to improve parking performance.
The low flux threshold level for determining a successful startup
(scaling: 129 = 100% flux). Please do not modify this parameter
without consulting a motor drive FAE.The low flux threshold level for
determining a successful startup.
The upper flux threshold level for determining a successful startup
(scaling: 64 = 100% flux). Please do not modify this parameter
without consulting a motor drive FAE.The high flux threshold level for
determining start-up failure.
If start-up fails, the user can program start-up retrial. This parameter
determines the number of start-up retries. A value of zero will disable
startup retrial. The maximum number of retries is 15.
During motor start-up, dc current is injected to the motor for
maximization of startup torque per ampere rating. Users are able to
use a higher level of dc current injection (ParkIRet scaling 255 =
Motor Rated Amp * 0.866) after two or more restarts. This is done to
increase the chance of a successful start-up.Start-up failure may be
caused by increased shaft friction. After first start-up retry, the
parking current can be increased to improve parking performance.
StartupRetrial Write Register Field Definitions
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46
IRMCK203
PhaseLossDetect Registers (Write Registers)
Byte
Offset
7
6
5
Bit Position
4
3
0x79
ParkTmRet
0x28
AdjPark1
0x29
AdjPark2
0x2A
RetryTm
2
1
0
PhaseLossDetect Write Register Map
Field
Name
AdjPark1
Access
(R/W)
W
Field Description
Anticipated W-phase motor current gain scaler used during initial
stage of Phase Loss detection.
W
Anticipated W-phase motor current gain scaler used during final
stage of Phase Loss detection.
W
Phase Loss detection current error thershold.
PhaseLossDetect Write Register Field Definitions
AdjPark2
PhsLosThr
D/AConverter Registers (Write Registers)
Byte
Offset
7
0x4F
6
5
Bit Position
4
3
2
1
0
DacSel
D/AConverter Write Register Map
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47
IRMCK203
Field
Name
DacSel
Access
(R/W)
W
Field Description
Selects D/A converter diagnostic outputs 0 - 3.
A value of 0 selects:
Data 0 = Alpha fluxFlux
Data 1 = Electrical Rotor angle
Data 2 = Alpha voltageTorque current
Data 3 = Closed loop/open loop status (0 = open, 1 = closed)
A value of 1 selects:
Data 0 = Alpha currentDC bus voltage
Data 1 = Torque current feedbackAlpha voltage
Data 2 = IQ refTorque current reference
Data 3 = Motor speed
A value of 2 selects:
Data 0 = Q-axis command voltage
Data 1 = D-axis command voltage
Data 2 = Alpha current
Data 3 = Beta current
A value of 3 selects:
Data 0 = Flux magnitude
Data 1 = Current error at parking
Data 2 = Parking diagnostic flag
Data 3 = W-phase current
D/AConverter Write Register Field Definitions
Factory Test Register (Write Register)
Byte
Offset
7
6
5
Bit Position
4
3
2
1
0
Test
0x58
Factory Write Register Map
Field
Name
Test
Access
(R/W)
W
Field Description
Reserved for factory use. Data written to this register could be read
from a read register at location 0x58.
Factory Write Register Field Definitions
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48
IRMCK203
Read Register Definitions
SystemStatus Register Group (Read Registers)
Byte
Offset
0x7
7
6
5
Bit Position
4
3
2
1
0
StartStop
FwdRev
ESTOP
PwrID
ExtCtrlR
Foc
EnbR
Pwm
EnbR
SystemStatus Read Register Map
Field
Name
PwmEnbR
FocEnbR
ExtCtrlR
Access
(R/W)
R
R
R
PwrID
ESTOP
FwdRev
R
R
R
StartStop
R
Field Description
PWM Enable bit status.
FOC Enable bit status.
Reflects the status of the ExtCtrl bit in the System Configuration write
register (address 0x50).
Power ID. 0 = 3 kW, 1 = 2 kW, 2 = 500 W.
User Interface emergency stop signal (1 – emergency stop)
User Interface “FWD/REVDIR" digital input status.
1 - Forward rotation request
0 - Reverse rotation request
User Interface “START/STOP" digital input status.
1 - Start
0 - Stop
SystemStatus Read Register Field Definitions
DcBusVoltage Register Group (Read Registers)
Byte
Offset
7
6
5
2
1
0
DcBusVolts (LSBs)
0xA
0xB
Bit Position
4
3
SPARE
Brake
DcBusVolts (MSBs)
DcBusVoltage Read Register Map
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
49
IRMCK203
Field
Name
DcBusVolts
Access
(R/W)
R
Brake
R
Field Description
DC Bus Voltage. Data range is 0 - 4095, which corresponds to a
DC bus voltage between 0 and 500 volts.
Brake signal status. 1 = Brake signal active.
DcBusVoltage Read Register Field Definitions
FocDiagnosticData Register Group (Read Registers)
Byte
Offset
7
6
Bit Position
4
3
5
1
0
RotatorAngle (LSB)
0xC
0xD
2
SPARE
Parking
Done
Start_
Fail
Closed_
Loop
RotatorAngle (MSB)
0xE
Id – Synchronous Frame Direct Current (LSBs)
0xF
Id – Synchronous Frame Direct Current (MSBs)
0x10
Iq – Synchronous Frame Quadrature Current (LSBs)
0x11
Iq – Synchronous Frame Quadrature Current (MSBs)
0x12
IqRef_C – Synchronous Frame Quadrature Current command (LSB)
0x13
IqRef_C – Synchronous Frame Quadrature Current command (MSB)
0x14
Flx_Alpha – Estimated Motor Flux (LSB)
0x15
Flx_Alpha – Estimated Motor Flux (MSB)
0x16
I_Alpha – Alpha Frame Current (LSB)
0x17
I_Alpha – Alpha Frame Current (MSB)
0x18
V_Alpha – Alpha Frame Voltage (LSB)
0x19
V_Alpha – Alpha Frame Voltage (MSB)
FocDiagnosticData Read Register Map
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
50
IRMCK203
Field
Name
Access
(R/W)
Field Description
Estimated rotor angle (electrical), which is used for synchronous
frame to stationary frame transformation. The scaling is 4096 = 2PI.
The range is 0 – 4095.
This is a drive control status flag which indicates that the drive has
R
switched from open-loop to closed-loop operation. The switch over is
done during drive start-up (initial speed ramping)
This is a drive control status flag indicating that the drive has failed to
R
start due to various reasons (for instance: shaft jam). The start-stop
sequencer uses this bit and parameter NumRetry to determine
whether a start-up retry should be activated.
This is a status flag indicating that the drive has finished obtaining the
R
initial rotor angle (parking) for motor startup. During drive start-up, the
first start-up stage is parking stage.
Synchronous or rotating frame direct and quadrature current values
R
in 2’s complement representation. The full scale current values range
from –16384 to 16383. (Scaling: 4095 = rated motor current)
Synchronous or rotating frame quadrature current command values
R
in 2’s complement representation. The full scale current values range
from –16384 to 16383.
R
Estimated motor flux value. Scaling is 5000 = rated motor flux.
Stationary frame current. Scaling is platform dependent (current
R
shunt resistor). Drive commissioning tool (Spreadsheet) provides
the scaling of I_Alpha (AiBi scale).
Stationary frame Alpha voltage. This voltage is constructed by dc bus
R
voltage and modulation index in the Stationary frame. The scaling is
platform dependent.
FocDiagnosticData Read Register Field Definitions
RotatorAnlge
R
Closed_Loop
Start_Fail
Parking
Done
Id, Iq
IqRef_C
Flx_Alpha
I_Alpha
V_Alpha
FaultStatus Register Group (Read Registers)
The Fault Status register records fault conditions that occur during drive operation. When any of these fault
conditions occur, the PWM output is automatically disabled. The user should monitor this register continuously for
fault conditions. A fault condition can be cleared by writing a “1” to the FaultClr bit in the FaultControl write
register group. (This does not automatically re-enable PWM output.)
Byte
Offset
0x1E
7
6
5
PhsLoss
Flt
RetryFlt
ZeroSpd
Flt
Bit Position
4
3
ExecTm
Flt
OvrSpdFlt
2
1
0
OvFlt
LvFlt
GatekillFlt
FaultStatus Read Register Map
Field
Name
GatekillFlt
LvFlt
Access
(R/W)
R
R
Field Description
Filtered and latched version of IR2137 FAULT output.
DC bus low voltage fault. This fault occurs if the DC bus drops
below 120V.
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
51
IRMCK203
Field
Name
OvFlt
Access
(R/W)
R
OvrSpdFlt
R
ExecTmFlt
ZeroSpdFlt
R
R
RetryFlt
R
PhsLossFlt
R
Field Description
DC bus overvoltage fault. This fault occurs if the DC bus voltage
exceeds 410V.
Over speed fault. This fault occurs whenever the motor reaches the
positive or negative limits. The user should use the scale factor in
the SpdScl field of the VelocityControl write register group to scale
the motor speed so that it falls between -16384 and +16383 with
these limits as the over speed condition.
Execution time fault.
Zero Speed fault. When speed is less than MinSpd/2 (half
minimum speed) for a continuous period of 2 4 seconds, the zero
speed fault will be set.
Start-up retry fault. After a certain number (determined by parameter
NumRetries) of start-up failures, this fault will be set.
Phase loss fault. Drive to motor phase connection may be loose.
FaultStatus Read Register Field Definitions
VelocityStatus Register Group (Read Registers)
Byte
Offset
7
6
5
Bit Position
4
3
0x26
Spd (LSBs)
0x27
Spd (MSBs)
2
1
0
VelocityStatus Read Register Map
Field
Name
Spd
Access
(R/W)
R
Field Description
Current motor speed in SPEED units. (See the description of SpdScl
in the VelocityControl write register group.)
VelocityStatus Read Register Field Definitions
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52
IRMCK203
CurrentFeedbackOffset Register Group (Read Registers)
Byte
Offset
7
6
5
Bit Position
4
3
2
1
0
IfbVOffs (LSBs)
(R)
0x30
IfbWOffs (LSBs)
(R)
0x31
IfbVOffs (MSBs)
(R)
IfbWOffs (MSBs)
(R)
0x32
CurrentFeedbackOffset Read Register Map
Field
Name
Access
(R/W)
Field Description
Current feedback offset values from the last IFB Offset calculation.
These values are automatically applied to each current feedback
measurement value whenever the IfbOffsEnb bit in the
SystemControl write register group is set.
CurrentFeedbackOffset Read Register Field Definitions
IfbVOffs,
IfbWOffs
R
EepromStatus Registers (Read Registers)
Byte
Offset
7
6
5
Bit Position
4
3
2
1
SPARE
0x38
0x39
EdDataR
(R)
0x3A
EeAddrR
(R)
0
EeBusy
EepromStatus Read Register Map
Field
Name
EeBusy
Access
(R/W)
R
Field Description
I2C EEPROM Interface busy bit. The user should wait for this bit to
clear before initiating EEPROM read or write operations.
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
53
IRMCK203
Field
Name
EeDataR
Access
(R/W)
R
EeAddrR
R
Field Description
EEPROM Data Register. Contains the data from the last EEPROM
read operation. Note that writing to the EeRst field in the
EepromControl write register group invalidates this register.
EEPROM Address read register shows the value stored in EEPROM
at the offset of the EeAddrW write register (0x5D). Since this
address in the EEPROM contains the BPIRMCK203 register map
version, the user can read this field to determine whether or not the
write registers were initialized at power on.
EepromStatus Read Register Field Definitions
FOCDiagnosticDataSupplement Register Group (Read Registers)
Byte
Offset
7
6
5
2
1
0
ElecAngR (LSBs)
(R)
0x3C
0x3D
Bit Position
4
3
SPARE
ElecAngR (MSBs)
(R)
0x3E
SpdRef (LSBs)
(R)
0x3F
SpdRef (MSBs)
(R)
0x40
SpdErr (LSBs)
(R)
0x41
SpdErr (MSBs)
(R)
0x42
IqRefR (LSBs)
(R)
0x43
IqRefR (MSBs)
(R)
FOCDiagnosticDataSupplement Read Register Map
Field
Name
ElecAngR
SpdRef
SpdErr
IqRefR
Access Field Description
(R/W)
R
Electrical angle.
R
Speed PI controller reference input.
R
Speed PI controller error.
R
Speed PI controller output.
FOCDiagnosticDataSupplement Read Register Field Definitions
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
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IRMCK203
ProductIdentification Registers (Read Registers)
Byte
Offset
7
6
Bit Position
4
3
5
0x7C
ProductID
(R)
0x7D
RegMapVerID
(R)
0x7E
RevCodeID (LSBs)
(R)
0x7F
RevCodeID (MSBs)
(R)
2
1
0
ProductIdentification Read Register Map
Field
Name
ProductID
RegMapVerID
RevCodeID
Access
(R/W)
R
R
R
Field Description
Product identification code.
Current register map version code.
IRMCK203 Revision Code. Revision code format is “XX.XX”, where
each “X” is a 4-bit hexadecimal number.
ProductIdentification Read Register Field Definitions
Factory Register (Read Register)
Byte
Offset
7
6
5
Bit Position
4
3
2
1
0
Test
(R)
0x58
Factory Read Register Map
Field
Name
Test
Access
(R/W)
R
Field Description
Data value resulting from a write to write register 0x58.
factory use only.
Factory Read Register Field Definitions
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
Used for
55
IRMCK203
Appendix B
Package
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
56
IRMCK203
IR WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245, Tel: (310) 252-7105
Data and specifications subject to change without notice. 4/13/2004
http://www.irf.com
Sales Offices, Agents and Distributors in Major Cities Throughout the World.
This document is the property of International Rectifier and may not be copied or distributed without expressed consent.
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