IRF IRMCF312 Dual channel sensorless motor control ic Datasheet

Data Sheet No. PD60300-A
IRMCF312
Dual Channel Sensorless Motor Control IC
for Appliances
Features
Product Summary
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Maximum crystal frequency
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TM
MCE (Motion Control Engine) - Hardware based
computation engine for high efficiency sinusoidal
sensorless control of permanent magnet AC motor
Integrated Power Factor Correction control
Supports both interior and surface permanent
magnet motors
Built-in hardware peripheral for single shunt
current feedback reconstruction
No external current or voltage sensing operational
amplifier required
Dual channel three/two-phase Space Vector PWM
Three-channel analog output (PWM)
Embedded 8-bit high speed microcontroller (8051)
for flexible I/O and man-machine control
JTAG programming port for emulation/debugger
Two serial communication interface (UART)
I2C/SPI serial interface
Watchdog timer with independent analog clock
Three general purpose timers/counters
Two special timers: periodic timer, capture timer
60 MHz
Maximum internal clock (SYSCLK) frequency
Sensorless control computation time
TM
MCE
computation data range
128 MHz
11 μsec typ
16 bit signed
Program RAM loaded from external EEPROM 48K bytes
Data RAM
8K bytes
GateKill latency (digital filtered)
2 μsec
PWM carrier frequency counter
16 bits/ SYSCLK
A/D input channels
11
A/D converter resolution
12 bits
A/D converter conversion speed
2 μsec
8051 instruction execution speed
Analog output (PWM) resolution
UART baud rate (typ)
Number of I/O (max)
Package (lead-free)
2 SYSCLK
8 bits
57.6K bps
36
QFP100
External EEPROM and internal RAM facilitate
debugging and code development
Pin compatible with IRMCK312, OTP-ROM version
1.8V/3.3V CMOS
Description
IRMCF312 is a high performance RAM based motion control IC designed primarily for appliance applications. IRMCF312 is
designed to achieve low cost and high performance control solutions for advanced inverterized appliance motor control.
IRMCF312 contains two computation engines. One is Motion Control Engine (MCETM) for sensorless control of permanent
magnet motors; the other is an 8-bit high-speed microcontroller (8051). Both computation engines are integrated into one
monolithic chip. The MCETM contains a collection of control elements such as Proportional plus Integral, Vector rotator, Angle
estimator, Multiply/Divide, Low loss SVPWM, Single Shunt IFB. The user can program a motion control algorithm by
connecting these control elements using a graphic compiler. Key components of the sensorless control algorithms, such as
the Angle Estimator, are provided as complete pre-defined control blocks implemented in hardware. A unique analog/digital
circuit and algorithm to fully support single shunt current reconstruction is also provided. The 8051 microcontroller performs 2cycle instruction execution (60MIPS at 120MHz). The MCE and 8051 microcontroller are connected via dual port RAM to
process signal monitoring and command input. An advanced graphic compiler for the MCETM is seamlessly integrated into the
MATLAB/Simulink environment, while third party JTAG based emulator tools are supported for 8051 developments.
IRMCF312 comes with a small QFP100 pin lead-free package.
Rev 1.1
IRMCF312
TABLE OF CONTENTS
1
2
3
4
Overview...................................................................................................................................... 4
IRMCF312 Block Diagram and Main Functions ........................................................................ 5
Pinout........................................................................................................................................... 7
Input/Output of IRMCF312......................................................................................................... 8
4.1 8051 Peripheral Interface Group........................................................................................... 9
4.2 Motion Peripheral Interface Group ..................................................................................... 10
4.3 Analog Interface Group ...................................................................................................... 11
4.4 Power Interface Group ........................................................................................................ 12
4.5 Test Interface....................................................................................................................... 12
5 Application Connections ........................................................................................................... 13
6 DC Characteristics ..................................................................................................................... 14
6.1 Absolute Maximum Ratings ............................................................................................... 14
6.2 System Clock Frequency and Power Consumption............................................................ 14
6.3 Digital I/O DC Characteristics............................................................................................ 15
6.4 PLL and Oscillator DC Characteristics............................................................................... 16
6.5 Analog I/O DC Characteristics ........................................................................................... 16
6.6 Analog I/O DC Characteristics ........................................................................................... 17
6.7 Under Voltage Lockout DC Characteristics ....................................................................... 18
6.8 CMEXT and AREF Characteristics.................................................................................... 18
7 AC Characteristics ..................................................................................................................... 19
7.1 PLL AC Characteristics ...................................................................................................... 19
7.2 Analog to Digital Converter AC Characteristics ................................................................ 20
7.3 Op Amp AC Characteristics ............................................................................................... 21
7.4 Op Amp AC Characteristics ............................................................................................... 21
7.5 SYNC to SVPWM and A/D Conversion AC Timing......................................................... 22
7.6 GATEKILL to SVPWM AC Timing.................................................................................. 23
7.7 Interrupt AC Timing ........................................................................................................... 23
7.8 I2C AC Timing .................................................................................................................... 24
7.9 SPI AC Timing.................................................................................................................... 25
7.9.1 SPI Write AC timing .................................................................................................... 25
7.9.2 SPI Read AC Timing.................................................................................................... 26
7.10
UART AC Timing ........................................................................................................... 27
7.11
CAPTURE Input AC Timing .......................................................................................... 28
7.12
JTAG AC Timing ............................................................................................................ 29
8 Pin List....................................................................................................................................... 30
9 Package Dimensions.................................................................................................................. 34
10
Part Marking Information....................................................................................................... 35
2
IRMCF312
TABLE OF FIGURES
Figure 1.
Figure 2.
Figure 3.
Figure 4.
Figure 5.
Figure 6.
Typical Application Block Diagram Using IRMCF312.................................................. 4
IRMCF312 Internal Block Diagram ................................................................................ 5
IRMCF312 Pin Configuration ......................................................................................... 7
Input/Output of IRMCF312 ............................................................................................. 8
Application Connection of IRMCF312 ......................................................................... 13
Clock Frequency vs. Power Consumption..................................................................... 14
TABLE OF TABLES
Table 1.
Table 2.
Table 3.
Table 4.
Table 5.
Table 6.
Table 7.
Table 8.
Table 9.
Table 10.
Table 11.
Table 12.
Table 13.
Table 14.
Table 15.
Table 16.
Table 17.
Table 18.
Table 19.
Table 20.
Table 21.
Table 22.
Absolute Maximum Ratings............................................................................................ 14
System Clock Frequency................................................................................................. 14
Digital I/O DC Characteristics ........................................................................................ 15
PLL DC Characteristics .................................................................................................. 16
Analog I/O DC Characteristics ....................................................................................... 16
Analog I/O DC Characteristics ....................................................................................... 17
UVcc DC Characteristics ................................................................................................ 18
CMEXT and AREF DC Characteristics.......................................................................... 18
PLL AC Characteristics .................................................................................................. 19
A/D Converter AC Characteristics................................................................................ 20
Current Sensing OP Amp AC Characteristics............................................................... 21
Voltage sensing OP Amp AC Characteristics............................................................... 21
SYNC AC Characteristics............................................................................................. 22
GATEKILL to SVPWM AC Timing ............................................................................ 23
Interrupt AC Timing...................................................................................................... 23
I2C AC Timing .............................................................................................................. 24
SPI Write AC Timing.................................................................................................... 25
SPI Read AC Timing..................................................................................................... 26
UART AC Timing......................................................................................................... 27
CAPTURE AC Timing ................................................................................................. 28
JTAG AC Timing.......................................................................................................... 29
Pin List .......................................................................................................................... 33
3
IRMCF312
1 Overview
IRMCF312 is a new International Rectifier integrated circuit device primarily designed as a onechip solution for complete inverter controlled appliance dual motor control applications. Unlike a
traditional microcontroller or DSP, the IRMCF312 provides a built-in closed loop sensorless
control algorithm using the unique Motion Control Engine (MCETM) for permanent magnet
motors. The MCETM consists of a collection of control elements, motion peripherals, a dedicated
motion control sequencer and dual port RAM to map internal signal nodes. IRMCF312 also
employs a unique single shunt current reconstruction circuit to eliminate additional analog/digital
circuitry and enables a direct shunt resistor interface to the IC. The sensorless control is the same
for both motors with a single shunt current sensing capability. Motion control programming is
achieved using a dedicated graphical compiler integrated into the MATLAB/SimulinkTM
development environment. Sequencing, user interface, host communication, and upper layer
control tasks can be implemented in the 8051 high-speed 8-bit microcontroller. The 8051
microcontroller is equipped with a JTAG port to facilitate emulation and debugging tools. Figure 1
shows a typical application schematic using IRMCF312.
IRMCF312 is intended for development purpose and contains 48K bytes of RAM, which can be
loaded from external EEPROM for 8051 program execution. For high volume production,
IRMCK312 contains OTP ROM in place of program RAM to reduce the cost. Both IRMCF312
and IRMCK312 come in the same 100-pin QFP package with identical pin configuration to
facilitate PC board layout and transition to mass production
Figure 1. Typical Application Block Diagram Using IRMCF312
4
IRMCF312
2 IRMCF312 Block Diagram and Main Functions
Motion Control Bus
8bit uP Address/Data bus
IRMCF312 block diagram is shown in Figure 2.
Figure 2. IRMCF312 Internal Block Diagram
IRMCF312 contains the following functions for sensorless AC motor control applications:
•
Motion Control Engine (MCETM)
o Proportional plus Integral block
o Low pass filter
o Differentiator and lag (high pass filter)
o Ramp
o Limit
o Angle estimate (sensorless control)
o Inverse Clark transformation
o Vector rotator
o Bit latch
5
IRMCF312
o
o
o
o
o
o
o
o
o
o
o
o
o
o
o
o
•
Peak detect
Transition
Multiply-divide (signed and unsigned)
Divide (signed and unsigned)
Adder
Subtractor
Comparator
Counter
Accumulator
Switch
Shift
ATAN (arc tangent)
Function block (any curve fitting, nonlinear function)
16-bit wide Logic operations (AND, OR, XOR, NOT, NEGATE)
MCETM program and data memory (6K byte). Note 1
MCETM control sequencer
8051 microcontroller
o Three 16-bit timer/counters
o 16-bit periodic timer
o 16-bit analog watchdog timer
o 16-bit capture timer
o Up to 36 discrete I/Os
o Eleven-channel 12-bit A/D
ƒ Five buffered channels (0 – 1.2V input)
ƒ Six unbuffered channels (0 – 1.2V input)
o JTAG port (4 pins)
o Up to three channels of analog output (8-bit PWM)
o Two UART
o I2C/SPI port
o 48K byte program RAM loaded from external EEPROM
o 2K byte data RAM. Note 1
Note 1: Total size of RAM is 8K byte including MCE program, MCE data, and
8051 data. Different sizes can be allocated depending on applications.
6
IRMCF312
3 Pinout
Figure 3. IRMCF312 Pin Configuration
Attention: Pin 51 must be left floating. Do not connect.
7
IRMCF312
4 Input/Output of IRMCF312
All I/O signals of IRMCF312 are shown in Figure 4. All I/O pins are 3.3V logic interface except
A/D interface pins.
Figure 4. Input/Output of IRMCF312
8
IRMCF312
4.1
8051 Peripheral Interface Group
UART Interface
P1.1/RXD
P1.2/TXD
P3.6/RXD1
P3.7/TXD1
Input, Receive data to IRMCF312, can be configured as P1.1
Output, Transmit data from IRMCF312, can be configured as P1.2
Input, 2nd channel Receive data to IRMCF312, can be configured as P3.6
Output, 2nd channel Transmit data from IRMCF312, can be configured as
P3.7
Discrete I/O Interface
P1.0/T2
Input/output port 1.0, can be configured as Timer/Counter 2 input
P1.3/SYNC/SCK Input/output port 1.3, can be configured as SYNC output or SPI clock,
needs to be pulled up to VDD1 in order to boot from I2C EEPROM
P1.4/CAP
Input/output port 1.4, can be configured as Capture Timer input
P1.5
Input/output port 1.5
P1.6
Input/output port 1.6
P1.7
Input/output port 1.7
P2.0/NMI
Input/output port 2.0, can be configured as non-maskable interrupt
P2.1
Input/output port 2.1
P2.2
Input/output port 2.2
P2.3
Input/output port 2.3
P2.4
Input/output port 2.4
P2.5
Input/output port 2.5
P3.0/INT2/CS1 Input/output port 3.0, can be configured as external interrupt 2 or SPI
chip select 1
P3.2/INT0
Input/output port 3.2, can be configured as external interrupt 0
P3.3/INT1
Input/output port 3.3, can be configured as external interrupt 1
P3.4/T0
Input/output port 3.4, can be configured as Timer/Counter 0 input
P3.5/T1
Input/output port 3.5, can be configured as Timer/Counter 1 input
P4.0/INT3
Input/output port 4.0, can be configured as external interrupt 3
P4.1/INT4
Input/output port 4.1, can be configured as external interrupt 4
P4.2/INT5
Input/output port 4.2, can be configured as external interrupt 5
P4.3/INT6
Input/output port 4.3, can be configured as external interrupt 6
P4.4/INT7
Input/output port 4.4, can be configured as external interrupt 7
P4.5/INT8
Input/output port 4.5, can be configured as external interrupt 8
P4.6/INT9
Input/output port 4.6, can be configured as external interrupt 9
P4.7/INT10
Input/output port 4.7, can be configured as external interrupt 10
P5.0/PFCGKILL Input/output port 5.0, can be configured as PFCGKILL
P5.1/TMS
Input/output port 5.1, can be configured as JTAG TMS pin
P5.2/TDO
Input/output port 5.2, can be configured as JTAG TDO pin
P5.3/TDI
Input/output port 5.3, can be configured as JTAG TDI pin
9
IRMCF312
Analog Output Interface
P2.6/AOPWM0 Input/output, can be configured as 8-bit PWM output 0 with
programmable carrier frequency
P2.7/AOPWM1 Input/output, can be configured as 8-bit PWM output 1 with
programmable carrier frequency
P3.1/AOPWM2 Input/output, can be configured as 8-bit PWM output 2 with
programmable carrier frequency
Crystal Interface
XTAL0
XTAL1
Reset Interface
RESET
Input, connected to crystal
Output, connected to crystal
Inout, system reset, needs to be pulled up to VDD1 but doesn’t require
external RC time constant
I2C/SPI Interface
SCL/SO-SI
SDA/CS0
P3.0/INT2/CS1
Output, I2C clock output, SPI SO-SI
Input/output, I2C Data line, Chip Select 0 of SPI
Input/output port 3.0, can be configured as external interrupt 2 or SPI
chip select 1
P1.3/SYNC/SCK Input/output port 1.3, can be configured as SYNC output or SPI clock,
needs to be pulled up to VDD1 in order to boot from I2C EEPROM
4.2
Motion Peripheral Interface Group
PWM
CPWMUH
CPWMUL
CPWMVH
CPWMVL
CPWMWH
CPWMWL
FPWMUH
FPWMUL
FPWMVH
FPWMVL
FPWMWH
FPWMWL
PFCPWM
Output, motor 1 PWM phase U high side gate signal
Output, motor 1 PWM phase U low side gate signal
Output, motor 1 PWM phase V high side gate signal
Output, motor 1 PWM phase V low side gate signal
Output, motor 1 PWM phase W high side gate signal
Output, motor 1 PWM phase W low side gate signal
Output, motor 2 PWM phase U high side gate signal
Output, motor 2 PWM phase U low side gate signal
Output, motor 2 PWM phase V high side gate signal
Output, motor 2 PWM phase V low side gate signal
Output, motor 2 PWM phase W high side gate signal
Output, motor 2 PWM phase W low side gate signal
Output, PFC PWM
10
IRMCF312
Fault
CGATEKILL
Input, upon assertion, this negates all six PWM signals for motor 1,
programmable logic sense
P5.0/PFCGKILL Input, upon assertion, this negates PFCPWM signal, programmable logic
sense, can be configured as discrete I/O in which case CGATEKILL
negates PFCPWM
FGATEKILL
Input, upon assertion, this negates all six PWM signals for motor 2,
programmable logic sense
4.3
Analog Interface Group
AVDD
AVSS
AREF
CMEXT
IFBC+
IFBCIFBCO
IFBF+
IFBFIFBFO
IPFC+
IPFCIPFO
VAC+
VACVACO
VDC+
VDCAIN0/VDCO
AIN1
AIN2
Analog power (1.8V)
Analog power return
Buffered 0.6V output
Unbuffered 0.6V, input to the AREF buffer, capacitor needs to be
connected.
Input, Operational amplifier positive input for shunt resistor current
sensing of motor 1
Input, Operational amplifier negative input for shunt resistor current
sensing of motor 1
Output, Operational amplifier output for shunt resistor current sensing of
motor 1
Input, Operational amplifier positive input for shunt resistor current
sensing of motor 2
Input, Operational amplifier negative input for shunt resistor current
sensing of motor 2
Output, Operational amplifier output for shunt resistor current sensing of
motor 2
Input, Operational amplifier positive input for PFC current sensing
Input, Operational amplifier negative input for PFC current sensing
Output, Operational amplifier output for PFC current sensing
Input, Operational amplifier positive input for PFC AC voltage sensing
Input, Operational amplifier negative input for PFC AC voltage sensing
Output, Operational amplifier output for PFC AC voltage sensing
Input, Operational amplifier positive input for DC bus voltage sensing
Input, Operational amplifier negative input for DC bus voltage sensing
Input/Output, Analog input channel 0 or Operational amplifier output for
DC bus voltage sensing
Input, Analog input channel 1 (0-1.2V), needs to be pulled down to
AVSS if unused
Input, Analog input channel 2 (0-1.2V), needs to be pulled down to
AVSS if unused
11
IRMCF312
AIN3
AIN4
AIN5
AIN6
4.4
Power Interface Group
VDD1
VDD2
VSS
PLLVDD
PLLVSS
4.5
Input, Analog input channel 3 (0-1.2V), needs to be pulled down to
AVSS if unused
Input, Analog input channel 4 (0-1.2V), needs to be pulled down to
AVSS if unused
Input, Analog input channel 5 (0-1.2V), needs to be pulled down to
AVSS if unused
Input, Analog input channel 6 (0-1.2V), needs to be pulled down to
AVSS if unused
Digital power for I/O (3.3V)
Digital power for core logic (1.8V)
Digital common
PLL power (1.8V)
PLL ground return
Test Interface
TSTMOD
P5.3/TDI
P5.1/TMS
TCK
P5.2/TDO
Must be tied to VSS, used only for factory testing.
Input, JTAG test data input
Input, JTAG test mode select
Input, JTAG test clock
Output, JTAG test data output
12
IRMCF312
5 Application Connections
Typical application connection is shown in Figure 5. All components necessary to implement a
complete sensorless drive control algorithm are shown connected to IRMCF312.
Figure 5. Application Connection of IRMCF312
13
IRMCF312
6 DC Characteristics
6.1
Absolute Maximum Ratings
Symbol
VDD1
VDD2
VIA
VID
TA
TS
Parameter
Min
Typ
Max
Supply Voltage
-0.3 V
3.6 V
Supply Voltage
-0.3 V
1.98 V
Analog Input Voltage
-0.3 V
1.98 V
Digital Input Voltage
-0.3 V
3.65 V
Ambient Temperature
-40 ˚C
85 ˚C
Storage Temperature
-65 ˚C
150 ˚C
Table 1. Absolute Maximum Ratings
Condition
Respect to VSS
Respect to VSS
Respect to AVSS
Respect to VSS
Caution: Stresses beyond those listed in “Absolute Maximum Ratings” may cause permanent
damage to the device. These are stress ratings only and function of the device at these or any other
conditions beyond those indicated in the operational sections of the specifications are not implied.
System Clock Frequency and Power Consumption
Symbol
SYSCLK
Parameter
Min
Typ
Max
System Clock
32
128
Table 2. System Clock Frequency
Unit
MHz
240
200
160
Power (mW)
6.2
120
80
VDD2 (1.8V)
40
VDD1 (3.3V)
Total
0
0
50
100
Clock Frequency (MHz)
150
Figure 6. Clock Frequency vs. Power Consumption
14
IRMCF312
6.3
Digital I/O DC Characteristics
Symbol
VDD1
VDD2
VIL
VIH
CIN
IL
IOL1(2)
IOH1
IOL2
(2)
(3)
IOH2(3)
Parameter
Min
Typ
Max
Supply Voltage
3.0 V
3.3 V
3.6 V
Supply Voltage
1.62 V
1.8 V
1.98 V
Input Low Voltage
-0.3 V
0.8 V
Input High Voltage
2.0 V
3.6 V
Input capacitance
3.6 pF
Input leakage current
±10 nA
±1 μA
Low level output
8.9 mA
13.2 mA
15.2 mA
current
High level output
12.4 mA
24.8 mA
38 mA
current
Low level output
17.9 mA
26.3 mA
33.4 mA
current
High level output
24.6 mA
49.5 mA
81 mA
current
Table 3. Digital I/O DC Characteristics
Condition
Recommended
Recommended
Recommended
Recommended
(1)
VO = 3.3 V or 0 V
VOL = 0.4 V
(1)
VOH = 2.4 V
(1)
VOL = 0.4 V
(1)
VOH = 2.4 V
(1)
Note:
(1) Data guaranteed by design.
(2) Applied to SCL/SO-SI, SDA/CS0 pins.
(3) Applied to P1.0/T2, P1.1/RXD, P1.2/TXD, P1.3/SYNC/SCK, P1.4/CAP, P1.5, P1.6, P1.7,
P2.0/NMI, P2.1, P2.2, P2.3, P2.4, P2.5, P2.6/AOPWM0, P2.7/AOPWM1, P3.0/INT2/CS1,
P3.1/AOPWM2, P3.2/INT0, P3.3/INT1, P3.4/T0, P3.5/T1, P3.6/RXD1, P3.7/TXD1,
P4.0/INT3, P4.1/INT4, P4.2/INT5, P4.3/INT6, P4.4/INT7, P4.5/INT8, P4.6/INT9,
P4.7/INT10, P5.0/PFCGKILL, P5.1/TMS, P5.2/TDO, P5.3/TDI, CGATEKILL,
FGATEKILL, CPWMUL, CPWMUH, CPWMVL, CPWMVH, CPWMWL, CPWMWH,
FPWMUL, FPWMUH, FPWMVL, FPWMVH, FPWMWL, FPWMWH, and PFCPWM
pins.
15
IRMCF312
6.4
PLL and Oscillator DC Characteristics
Symbol
VPLLVDD
VIL OSC
VIH OSC
Parameter
Supply Voltage
Oscillator Input Low
Voltage
Oscillator Input High
Voltage
Table 4.
Min
1.62 V
VPLLVSS
Typ
1.8 V
-
0.8*
Max
1.92 V
0.2*
VPLLVDD
VPLLVDD
VPLLVDD
PLL DC Characteristics
Condition
Recommended
VPLLVDD = 1.8 V
(1)
VPLLVDD = 1.8 V
(1)
Note:
(1) Data guaranteed by design.
6.5
Analog I/O DC Characteristics
- OP amps for current sensing (IFBC+, IFBC-, IFBCO, IFBF+, IFBF-, IFBFO, IPFC+, IPFC-,
IPFCO)
CAREF = 1nF, CMEXT= 100nF. Unless specified, Ta = 25˚C.
Symbol
Parameter
Min
Typ
VAVDD
Supply Voltage
1.71 V
1.8 V
VOFFSET
Input Offset Voltage
VI
Input Voltage Range
0V
VOUTSW
OP amp output
50 mV
(1)
operating range
CIN
Input capacitance
3.6 pF
RFDBK
OP amp feedback
5 kΩ
resistor
OP GAINCL
CMRR
ISRC
ISNK
Max
1.89 V
26 mV
1.2 V
1.2 V
Condition
Recommended
VAVDD = 1.8 V
Recommended
VAVDD = 1.8 V
20 kΩ
(1)
Operating Close loop
80 db
Gain
Common Mode
80 db
Rejection Ratio
Op amp output source
1 mA
current
Op amp output sink
100 μA
current
Table 5. Analog I/O DC Characteristics
(1)
Requested
between op amp
output and
negative input
(1)
VOUT = 0.6 V
(1)
VOUT = 0.6 V
(1)
Note:
(1) Data guaranteed by design.
16
IRMCF312
6.6
Analog I/O DC Characteristics
- OP amps for voltage sensing (VAC+,VAC-,VACO, VDC+, VDC-, VDCO)
CAREF = 1nF, CMEXT= 100nF. Unless specified, Ta = 25˚C.
Symbol
Parameter
Min
Typ
Max
VAVDD
Supply Voltage
1.71 V
1.8 V
1.89 V
VOFFSET
Input Offset Voltage
26 mV
VI
Input Voltage Range
0V
1.2 V
VOUTSW
OP amp output
50 mV
1.2 V
(1)
operating range
CIN
Input capacitance
3.6 pF
OP GAINCL
Operating Close loop
80 db
Gain
CMRR
Common Mode
80 db
Rejection Ratio
ISRC
Op amp output source
5 mA
current
ISNK
Op amp output sink
500 μA
current
Table 6. Analog I/O DC Characteristics
Condition
VAVDD = 1.8 V
VAVDD = 1.8 V
(1)
(1)
(1)
VOUT = 0.6 V
(1)
VOUT = 0.6 V
(1)
Note:
(1) Data guaranteed by design.
17
IRMCF312
6.7
Under Voltage Lockout DC Characteristics
- Based on AVDD (1.8V)
Unless specified, Ta = 25˚C.
Symbol
Parameter
Min
Typ
Max
UVCC+
UVcc positive going
1.53 V
1.66 V
1.71 V
Threshold
UVCCUVcc negative going
1.52 V
1.62 V
1.71 V
Threshold
UVCCH
UVcc Hysteresys
40 mV
Table 7. UVcc DC Characteristics
6.8
Condition
VDD1 = 3.3 V
VDD1 = 3.3 V
CMEXT and AREF Characteristics
CAREF = 1nF, CMEXT= 100nF. Unless specified, Ta = 25˚C.
Condition
Symbol
Parameter
Min
Typ
Max
VCM
CMEXT voltage
495 mV
600 mV
700 mV
VAVDD = 1.8 V
VAREF
Buffer Output Voltage
495 mV
600 mV
700 mV
VAVDD = 1.8 V
(1)
1 mV
Load regulation (VDCΔVo
0.6)
(1)
PSRR
Power Supply Rejection
75 db
Ratio
Table 8. CMEXT and AREF DC Characteristics
Note:
(1) Data guaranteed by design.
18
IRMCF312
7 AC Characteristics
7.1
PLL AC Characteristics
Symbol
FCLKIN
FPLL
FLWPW
JS
D
TLOCK
Parameter
Min
Typ
Max
Condition
(1)
Crystal input
3.2 MHz
4 MHz
60 MHz
frequency
(see figure below)
Internal clock
32 MHz
50 MHz
128 MHz (1)
frequency
(1)
Sleep mode output FCLKIN ÷ 256
frequency
(1)
Short time jitter
200 psec
(1)
Duty cycle
50 %
PLL lock time
500 μsec (1)
Table 9. PLL AC Characteristics
Note:
(1) Data guaranteed by design.
R1=1M
R2=10
Xtal
C1=30PF
C2=30PF
19
IRMCF312
7.2
Analog to Digital Converter AC Characteristics
Unless specified, Ta = 25˚C.
Symbol
Parameter
TCONV
Conversion time
THOLD
Sample/Hold
maximum hold time
Min
-
Typ
-
Max
2.05 μsec
10 μsec
Condition
(1)
Voltage droop ≤
15 LSB
(see figure below)
Table 10. A/D Converter AC Characteristics
Note:
(1) Data guaranteed by design.
Input Voltage
Voltage droop
S/H Voltage
tSAMPLE
THOLD
20
IRMCF312
7.3
Op Amp AC Characteristics
- OP amps for current sensing (IFBC+, IFBC-, IFBCO, IFBF+, IFBF-, IFBFO, IPFC+, IPFC-,
IPFCO)
Unless specified, Ta = 25˚C.
Symbol
Parameter
OPSR
OP amp slew rate
OPIMP
TSET
Min
-
Typ
10 V/μsec
Max
-
-
108 Ω
400 ns
-
OP input impedance
Settling time
Condition
VAVDD = 1.8 V,
CL = 33 pF (1)
(1)
VAVDD = 1.8 V,
CL = 33 pF (1)
Table 11. Current Sensing OP Amp AC Characteristics
Note:
(1) Data guaranteed by design.
7.4
Op Amp AC Characteristics
- OP amps for voltage sensing (VAC+,VAC-,VACO, VDC+, VDC-, VDCO)
Unless specified, Ta = 25˚C.
Symbol
Parameter
OPSR
OP amp slew rate
OPIMP
TSET
OP input impedance
Settling time
Min
Typ
2.5 V/μsec
Max
-
-
108 Ω
650 ns
-
Condition
VAVDD = 1.8 V,
CL = 33 pF (1)
(1)
VAVDD = 1.8 V,
CL = 33 pF (1)
Table 12. Voltage sensing OP Amp AC Characteristics
Note:
(1) Data guaranteed by design.
21
IRMCF312
7.5
SYNC to SVPWM and A/D Conversion AC Timing
twSYNC
SYNC
tdSYNC1
IU,IV,IW
tdSYNC2
AINx
tdSYNC3
PWMUx,PWMVx,PWMWx
Unless specified, Ta = 25˚C.
Symbol
Parameter
Min
Typ
Max
twSYNC
SYNC pulse width
32
tdSYNC1
SYNC to current
100
feedback conversion
time
tdSYNC2
SYNC to AIN0-6
200
analog input
conversion time
tdSYNC3
SYNC to PWM output
2
delay time
Table 13. SYNC AC Characteristics
Unit
SYSCLK
SYSCLK
SYSCLK
(1)
SYSCLK
Note:
(1) AIN1 through AIN6 channels are converted once every 6 SYNC events
22
IRMCF312
7.6
GATEKILL to SVPWM AC Timing
Unless specified, Ta = 25˚C.
Symbol
Parameter
Min
Typ
Max
twGK
GATEKILL pulse
32
width
tdGK
GATEKILL to PWM
100
output delay
Table 14. GATEKILL to SVPWM AC Timing
7.7
Unit
SYSCLK
SYSCLK
Interrupt AC Timing
Unless specified, Ta = 25˚C.
Symbol
Parameter
Min
Typ
Max
twINT
INT0, INT1 Interrupt
4
Assertion Time
tdINT
INT0, INT1 latency
4
Table 15. Interrupt AC Timing
Unit
SYSCLK
SYSCLK
23
IRMCF312
7.8
I2C AC Timing
TI2CLK
TI2CLK
SCL
tI2ST1
tI2WSETUP
tI2ST2
tI2WHOLD
tI2RSETUP
tI2EN1
tI2RHOLD
tI2EN2
SDA
Unless specified, Ta = 25˚C.
Symbol
Parameter
TI2CLK
I2C clock period
tI2ST1
I2C SDA start time
tI2ST2
I2C SCL start time
tI2WSETUP
I2C write setup time
tI2WHOLD
I2C write hold time
tI2RSETUP
I2C read setup time
tI2RHOLD
I2C read hold time
Min
Typ
10
0.25
0.25
0.25
0.25
2
(1)
I C filter time
1
Table 16. I2C AC Timing
Max
8192
-
Unit
SYSCLK
TI2CLK
TI2CLK
TI2CLK
TI2CLK
SYSCLK
SYSCLK
Note:
(1) I2C read setup time is determined by the programmable filter time applied to I2C
communication.
24
IRMCF312
7.9
SPI AC Timing
7.9.1 SPI Write AC timing
Unless specified, Ta = 25˚C.
Symbol
Parameter
Min
Typ
Max
TSPICLK
SPI clock period
4
tSPICLKHT
SPI clock high time
1/2
tSPICLKLT
SPI clock low time
1/2
tCSDELAY
CS to data delay time
10
tWRDELAY
CLK falling edge to data
10
delay time
tCSHIGH
CS high time between two
1
consecutive byte transfer
tCSHOLD
CS hold time
1
Table 17. SPI Write AC Timing
Unit
SYSCLK
TSPICLK
TSPICLK
nsec
nsec
TSPICLK
TSPICLK
25
IRMCF312
7.9.2 SPI Read AC Timing
Unless specified, Ta = 25˚C.
Symbol
Parameter
Min
Typ
Max
TSPICLK
SPI clock period
4
tSPICLKHT
SPI clock high time
1/2
tSPICLKLT
SPI clock low time
1/2
tCSRD
CS to data delay time
10
tRDSU
SPI read data setup time
10
tRDHOLD
SPI read data hold time
10
tCSHIGH
CS high time between two
1
consecutive byte transfer
tCSHOLD
CS hold time
1
Table 18. SPI Read AC Timing
Unit
SYSCLK
TSPICLK
TSPICLK
nsec
nsec
nsec
TSPICLK
TSPICLK
26
IRMCF312
7.10 UART AC Timing
TBAUD
TXD
Start Bit
Data and Parity Bit
Stop Bit
RXD
TUARTFIL
Unless specified, Ta = 25˚C.
Symbol
Parameter
Min
Typ
TBAUD
Baud Rate Period
57600
1/16
TUARTFIL
UART sampling filter
period (1)
Table 19. UART AC Timing
Max
-
Unit
bit/sec
TBAUD
Note:
(1) Each bit including start and stop bit is sampled three times at center of a bit at an interval of
1/16 TBAUD. If three sampled values do not agree, then UART noise error is generated.
27
IRMCF312
7.11 CAPTURE Input AC Timing
Unless specified, Ta = 25˚C.
Symbol
Parameter
Min
Typ
Max
TCAPCLK
CAPTURE input
8
period
tCAPHIGH
CAPTURE input high
4
time
tCAPLOW
CAPTURE input low
4
time
tCRDELAY
CAPTURE falling edge
4
to capture register latch
time
tCLDELAY
CAPTURE rising edge
4
to capture register latch
time
tINTDELAY
CAPTURE input
4
interrupt latency time
Table 20. CAPTURE AC Timing
Unit
SYSCLK
SYSCLK
SYSCLK
SYSCLK
SYSCLK
SYSCLK
28
IRMCF312
7.12 JTAG AC Timing
TJCLK
TCK
tJHIGH
tJLOW
tCO
TDO
tJSETUP
tJHOLD
TDI/TMS
Unless specified, Ta = 25˚C.
Symbol
Parameter
Min
Typ
TJCLK
TCK Period
tJHIGH
TCK High Period
10
tJLOW
TCK Low Period
10
tCO
TCK to TDO propagation
0
delay time
tJSETUP
TDI/TMS setup time
4
tJHOLD
TDI/TMS hold time
0
Table 21. JTAG AC Timing
Max
50
5
Unit
MHz
nsec
nsec
nsec
-
nsec
nsec
29
IRMCF312
8 Pin List
Pin
Number
Pin Name
Internal IC
Pull-up
/Pull-down
Pin
Type
1
2
3
XTAL0
XTAL1
P1.0/T2
I
O
I/O
4
5
P1.1/RXD
P1.2/TXD
I/O
I/O
6
P1.3/SYNC/
SCK
I/O
7
8
9
10
11
12
13
14
15
16
P1.4/CAP
P1.5
P1.6
P1.7
P4.3/INT6
P4.7/INT10
VDD2
VSS
VDD1
FGATEKILL
I/O
I/O
I/O
I/O
I/O
I/O
P
P
P
I
17
FPWMWL
18
FPWMWH
19
FPWMVL
20
FPWMVH
21
FPWMUL
22
FPWMUH
23
P2.0/NMI
I/O
24
25
26
P2.1
P2.2
P2.3
I/O
I/O
I/O
70 kΩ Pull
up
70 kΩ Pull
up
70 kΩ Pull
up
70 kΩ Pull
up
70 kΩ Pull
up
70 kΩ Pull
up
O
O
O
O
O
O
Description
Crystal input
Crystal output
Discrete programmable I/O or Timer/Counter 2
input
Discrete programmable I/O or UART receive input
Discrete programmable I/O or UART transmit
output
Discrete programmable I/O or SYNC output or SPI
clock output, needs to be pulled up to VDD1 in
order to boot from I2C EEPROM
Discrete programmable I/O or Capture Timer input
Discrete programmable I/O
Discrete programmable I/O
Discrete programmable I/O
Discrete programmable I/O or Interrupt 6
Discrete programmable I/O or Interrupt 10
1.8V digital power
Digital common
3.3V digital power
Fan PWM shutdown input, 2-μsec digital filter,
configurable either high or low true.
Fan PWM gate drive for phase W low side,
configurable either high or low true
Fan PWM gate drive for phase W high side,
configurable either high or low true
Fan PWM gate drive for phase V low side,
configurable either high or low true
Fan PWM gate drive for phase V high side,
configurable either high or low true
Fan PWM gate drive for phase U low side,
configurable either high or low true
Fan PWM gate drive for phase U high side,
configurable either high or low true
Discrete programmable I/O or Non Maskable
Interrupt
Discrete programmable I/O
Discrete programmable I/O
Discrete programmable I/O
30
IRMCF312
Pin
Number
27
28
29
Pin Name
Internal IC
Pull-up
/Pull-down
Pin
Type
31
32
33
34
35
36
37
38
39
40
P2.4
P2.5
P2.6/
AOPWM0
P2.7/
AOPWM1
VDD2
VSS
VSS
VDD1
P4.0/INT3
P4.4/INT7
IFBFIFBF+
IFBFO
AIN0/VDCO
41
42
43
44
45
VDC+
VDCAVDD
AVSS
AIN1
I
I
P
P
I
46
47
48
CMEXT
AREF
IFBC-
O
O
I
49
IFBC+
I
50
IFBCO
O
51
52
DNC
AIN2
I
53
AIN3
I
54
AIN4
I
55
AIN5
I
30
I/O
I/O
I/O
I/O
P
P
P
P
I/O
I/O
I
I
O
O
Description
Discrete programmable I/O
Discrete programmable I/O
Discrete programmable I/O or analog output 0
(PWM)
Discrete programmable I/O or analog output 1
(PWM)
1.8V digital power
Digital common
Digital common
3.3 V digital power
Discrete programmable I/O or Interrupt 3
Discrete programmable I/O or Interrupt 7
Fan single shunt current sensing OP amp input (-)
Fan single shunt current sensing OP amp input (+)
Fan single shunt current sensing OP amp output
Analog input channel 0 or DC bus voltage sensing
OP amp output
DC bus voltage sensing OP amp input (+)
DC bus voltage sensing OP amp input (-)
Analog power (1.8V)
Analog common
Analog input channel 1, 0-1.2V range, needs to be
pulled down to AVSS if unused
Unbuffered analog reference voltage output (0.6V)
Analog reference voltage output (0.6V)
Compressor single shunt current sensing OP amp
input (-)
Compressor single shunt current sensing OP amp
input (+)
Compressor single shunt current sensing OP amp
output
Do not connect.
Analog input channel 2, 0-1.2V range, needs to be
pulled down to AVSS if unused
Analog input channel 2, 0-1.2V range, needs to be
pulled down to AVSS if unused
Analog input channel 2, 0-1.2V range, needs to be
pulled down to AVSS if unused
Analog input channel 2, 0-1.2V range, needs to be
pulled down to AVSS if unused
31
IRMCF312
Pin
Number
Pin Name
56
AIN6
57
58
59
60
61
62
63
64
65
66
67
68
VAC+
VACVACO
IPFCO
IPFC+
IPFCP4.5/INT8
P4.1/INT4
VDD2
VSS
VDD1
CGATEKILL
69
CPWMWL
70
CPWMWH
71
CPWMVL
72
CPWMVH
73
CPWMUL
74
CPWMUH
75
P3.0/INT2/
CS1
P5.0/
PFCGKILL
76
77
PFCPWM
78
P3.1/
AOPWM2
P3.2/INT0
P3.3/INT1
P3.4/T0
79
80
81
Internal IC
Pull-up
/Pull-down
Pin
Type
I
I
I
O
O
I
I
I/O
I/O
P
P
P
I
70 kΩ Pull
up
70 kΩ Pull
up
70 kΩ Pull
up
70 kΩ Pull
up
70 kΩ Pull
up
70 kΩ Pull
up
O
O
O
O
O
O
I/O
I
70 kΩ Pull
up
O
I/O
I/O
I/O
I/O
Description
Analog input channel 2, 0-1.2V range, needs to be
pulled down to AVSS if unused
AC input voltage sensing OP amp input (+)
AC input voltage sensing OP amp input (-)
AC input voltage sensing OP amp output
PFC shunt current sensing OP amp output
PFC shunt current sensing OP amp input (+)
PFC shunt current sensing OP amp input (-)
Discrete programmable I/O or Interrupt 8
Discrete programmable I/O or Interrupt 4
1.8 V digital power
Digital common
3.3V digital power
Compressor PWM shutdown input, 2-μsec digital
filter, configurable either high or low true.
Compressor PWM gate drive for phase W low side,
configurable either high or low true
Compressor PWM gate drive for phase W high side,
configurable either high or low true
Compressor PWM gate drive for phase V low side,
configurable either high or low true
Compressor PWM gate drive for phase V high side,
configurable either high or low true
Compressor PWM gate drive for phase U low side,
configurable either high or low true
Compressor PWM gate drive for phase U high side,
configurable either high or low true
Discrete programmable I/O or INT2 digital input or
SPI Chip Select 1
Discrete programmable I/O or PFC PWM shutdown
input, 2-μsec digital filter, configurable either high
or low true.
PFC PWM gate drive, configurable either high or
low true
Discrete programmable I/O or analog output 2
(PWM)
Discrete programmable I/O or external interrupt 0
Discrete programmable I/O or external interrupt 1
Discrete programmable I/O or Timer/Counter 0
input
32
IRMCF312
Pin
Number
Pin Name
Internal IC
Pull-up
/Pull-down
Pin
Type
82
P3.5/T1
I/O
83
P3.6/RXD1
I/O
84
P3.7/TXD1
I/O
85
86
87
88
89
90
91
92
VSS
VSS
VDD1
P4.2/INT5
P4.6/INT9
SCL/SO-SI
SDA/CS0
P5.1/TMS
P
P
P
I/O
I/O
I/O
I/O
I/O
93
P5.2/TDO
I/O
94
95
96
P5.3/TDI
TCK
TSTMOD
I/O
I
I
97
98
99
100
RESET
VDD2
PLLVDD
PLLVSS
58 kΩ pull
down
Description
Discrete programmable I/O or Timer/Counter 1
input
Discrete programmable I/O or 2nd UART receive
input
Discrete programmable I/O or 2nd UART transmit
output
Digital common
Digital common
3.3V digital power
Discrete programmable I/O or Interrupt 5
Discrete programmable I/O or Interrupt 9
I2C clock output or SPI data
I2C data or SPI Chip Select 0
Discrete programmable I/O or JTAG test mode
select
Discrete programmable I/O or JTAG port test data
output
Discrete programmable I/O or JTAG test data input
JTAG test clock
Test mode. Must be tied to VSS. Factory use only
I/O
Reset, low true, Schmitt trigger input
P
1.8V digital power
P
1.8V PLL power.
P
PLL ground.
Table 22. Pin List
33
IRMCF312
9 Package Dimensions
34
IRMCF312
10 Part Marking Information
IRMCF312
Part Number
IR Logo
YWWP
Date Code
XXXXXX
Production Lot
Pin 1
Indentifier
Order Information
Lead-Free Part in 64-lead QFP
Moisture sensitivity rating – MSL3
Part number
IRMCF312TR
Order quantities
1000 parts on tape and reel in dry pack
The LQFP-100 is MSL3 qualified
This product has been designed and qualified for the industrial level
Qualification standards can be found at www.irf.com <http://www.irf.com>
IR WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245, Tel: (310) 252-7105
Data and specifications subject to change without notice. 12/05/2006
www.irf.com
35
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