Freescale MC34911BAC Lin system basis chip with dc motor pre-driver Datasheet

Freescale Semiconductor
Advance Information
Document Number: MC33911
Rev. 4.0, 2/2008
LIN System Basis Chip with DC
Motor Pre-driver
33911
The 33911 is a Serial Peripheral Interface (SPI)-controlled System
Basis Chip (SBC) combining many frequently used functions in an
MCU-based system, plus a Local Interconnect Network (LIN)
transceiver. The 33911 has a 5.0V - 60mA low dropout regulator with
full protection and reporting features. The device provides full SPIreadable diagnostics and a selectable timing watchdog for detecting
errant operation. The LIN Protocol Specification 2.0 compliant LIN
transceiver, has waveshaping circuitry that can be disabled for higher
data rates.
One 60mA high side switch and two 160mA low side switches with
output protection are available for driving resistive and inductive loads.
All outputs can be pulse-width modulated (PWM). Two high-voltage
inputs are available for use in contact monitoring, or as external wakeup inputs. These inputs can be used as high-voltage analog Inputs.
The voltage on theses pins is divided by a selectable ratio and
available via an analog multiplexer.
The 33911 has three main operating modes: Normal (all functions
available), Sleep (VDD off, wake-up via LIN, wake-up inputs (L1,L2),
cyclic sense, and forced wake-up), and Stop (VDD on with limited
current capability, wake-up via CS, LIN bus, wake-up inputs, cyclic
sense, forced wake-up, and external reset).
The 33911 is compatible with LIN Protocol Specification 2.0.
SYSTEM BASIS CHIP WITH LIN
2ND GENERATION
AC SUFFIX (Pb-FREE)
98ASH70029A
32-PIN LQFP
ORDERING INFORMATION
•
•
•
•
•
•
•
Temperature
Range (TA)
Device
Features
One 60mA high side switch and two 160mA low side switches
MC33911BAC/R2
Two high-voltage analog/logic inputs
MC34911BAC/R2
Full-duplex SPI Interface at frequencies up to 4MHz
LIN transceiver capable of up to 100kbps with wave shaping
Configurable window watchdog
5.0V low drop regulator with fault detection and low-voltage reset (LVR) circuitry
Pb-free packaging designated by suffix code AC
- 40°C to 125°C
32-LQFP
- 40°C to 85°C
33911
VBAT
VSENSE
HS1
VS1
VS2
L1
L2
VDD
PWMIN
ADOUT0
LS1
M
MOSI
MISO
SCLK
CS
RXD
TXD
IRQ
RST
LS2
WDCONF
LGND
PGND
AGND
MCU
LIN
LIN INTERFACE
Figure 1. 33911 Simplified Application Diagram
* This document contains certain information on a new product.
Specifications and information herein are subject to change without notice.
© Freescale Semiconductor, Inc., 2007. All rights reserved.
Package
INTERNAL BLOCK DIAGRAM
INTERNAL BLOCK DIAGRAM
VS2
INTERRUPT
CONTROL
MODULE
LVI, HVI, HTI, OCI
VS1
INTERNAL BUS
RST IRQ
VDD
AGND
VOLTAGE REGULATOR
RESET CONTROL
MODULE
LVR, HVR, HTR, WD
LS1
LOW SIDE
CONTROL
MODULE
WINDOW
WATCHDOG
MODULE
LS2
PGND
PWMIN
VS2
HIGH SIDE
CONTROL
MODULE
MISO
SCLK
SPI
&
CONTROL
ANALOG MULTIPLEXER
MOSI
CS
ADOUT0
WAKE-UP MODULE
VBAT
SENSE MODULE
VSENSE
CHIP TEMPERATURE
SENSE MODULE
ANALOG INPUT
MODULE
DIGITAL INPUT MODULE
RXD
TXD
HS1
L1
L2
LIN PHYSICAL
LAYER
LIN
LGND
WDCONF
Figure 2. 33911 Simplified Internal Block Diagram
33911
2
Analog Integrated Circuit Device Data
Freescale Semiconductor
PIN CONNECTIONS
AGND
VDD
NC*
VSENSE
NC
VS1
VS2
HS1
32
31
30
29
28
27
26
25
PIN CONNECTIONS
RXD
1
24
NC*
TXD
2
23
L1
MISO
3
22
L2
MOSI
4
21
NC*
SCLK
5
20
NC*
CS
6
19
LS1
ADOUT0
7
18
PGND
PWMIN
8
17
LS2
9
10
11
12
13
14
15
16
RST
IRQ
NC*
WDCONF
LIN
LGND
NC*
NC*
* Special Configuration Recommended /
Mandatory for Marked NC Pins
Figure 3. 33911 Pin Connections
Table 1. 33911 Pin Definitions
A functional description of each pin can be found in the Functional Pin Description section beginning on page 20.
Pin
Pin Name
Formal Name
Definition
1
RXD
Receiver Output
This pin is the receiver output of the LIN interface which reports the state of
the bus voltage to the MCU interface.
2
TXD
Transmitter Input
This pin is the transmitter input of the LIN interface which controls the state of
the bus output.
3
MISO
SPI Output
SPI (Serial Peripheral Interface) data output. When CS is high, pin is in the
high-impedance state.
4
MOSI
SPI Input
SPI (Serial Peripheral Interface) data input.
5
SCLK
SPI Clock
SPI (Serial Peripheral Interface) clock Input.
6
CS
SPI Chip Select
7
ADOUT0
Analog Output Pin 0
8
PWMIN
PWM Input
9
RST
Internal Reset I/O
Bidirectional reset I/O pin - driven low when any internal reset source is
asserted. RST is active low.
10
IRQ
Internal Interrupt
Output
Interrupt output pin, indicating wake-up events from Stop Mode or events from
Normal and Normal Request Modes. IRQ is active low.
SPI (Serial Peripheral Interface) chip select input pin. CS is active low.
Analog Multiplexer Output.
High side and low side pulse-width modulation input.
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
3
PIN CONNECTIONS
Table 1. 33911 Pin Definitions
A functional description of each pin can be found in the Functional Pin Description section beginning on page 20.
Pin
Pin Name
Formal Name
12
WDCONF
Watchdog
Configuration Pin
13
LIN
LIN Bus
14
LGND
LIN Ground Pin
17
LS2
19
LS1
18
PGND
22
L2
23
L1
25
HS1
26
VS2
27
VS1
29
Definition
This input pin is for configuration of the watchdog period and
allows the disabling of the watchdog.
This pin represents the single-wire bus transmitter and receiver.
This pin is the device LIN ground connection. It is internally connected to the
PGND pin.
Low Side Outputs
Relay drivers low side outputs.
Power Ground Pin
This pin is the device low side ground connection. It is internally connected to
the LGND pin.
Wake-Up Inputs
These pins are the wake-up capable digital inputs(1). In addition, all LX inputs
can be sensed analog via the analog multiplexer.
High Side Output
High side switch output.
Power Supply Pin
These pins are device battery level power supply pins. VS2 is supplying the
HS1 driver while VS1 supplies the remaining blocks.(2)
VSENSE
Voltage Sense Pin
Battery voltage sense input. (3)
31
VDD
Voltage Regulator
Output
+5.0V main voltage regulator output pin. (4)
32
AGND
Analog Ground Pin
This pin is the device analog ground connection.
Notes
1. When used as a digital input, a series 33kΩ resistor must be used to protect against automotive transients.
2. Reverse battery protection series diodes must be used externally to protect the internal circuitry.
3. This pin can be connected directly to the battery line for voltage measurements. The pin is self-protected against reverse battery
connections. It is strongly recommended to connect a 10kΩ resistor in series with this pin for protection purposes.
4. External capacitor (2µF < C < 100µF; 0.1Ω < ESR < 10Ω) required.
33911
4
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
Table 2. Maximum Ratings
All voltages are with respect to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or
permanent damage to the device.
Ratings
Symbol
Value
Unit
Normal Operation (DC)
VSUP(SS)
-0.3 to 27
Transient Conditions (load dump)
VSUP(PK)
-0.3 to 40
VDD
-0.3 to 5.5
VIN
-0.3 to VDD +0.3
VIN(IRQ)
-0.3 to 11
VHS1
- 0.3 to VSUP +0.3
V
VLS
-0.3 to 45
V
Normal Operation with a series 33kΩ resistor (DC)
VLxDC
-18 to 40
Transient input voltage with external component (according to ISO7637-2)
(See Figure 5, page 16)
VLxTR
±100
VVSENSE
-27 to 40
Normal Operation (DC)
VBUSDC
-18 to 40
Transient input voltage with external component (according to ISO7637-2)
(See Figure 4, page 16)
VBUSTR
-150 to 100
IVDD
Internally Limited
Human Body Model - LIN Pin(7)
VESD1-1
± 8000
Human Body Model - all other Pins(7)
VESD1-2
±2000
VESD2
± 200
VESD3-1
± 750
VESD3-2
± 500
VNC
Note 10
ELECTRICAL RATINGS
Supply Voltage at VS1 and VS2
Supply Voltage at VDD
Input / Output Pins Voltage
V
(5)
CS, RST, SCLK, PWMIN, ADOUT0, MOSI, MISO, TXD, RXD
V
V
Interrupt Pin (IRQ)(6)
HS1 Pin Voltage (DC)
LS1 and LS2 Pin Voltage (DC)
L1 and L2 Pin Voltage
VSENSE Pin Voltage (DC)
V
LIN Pin Voltage
VDD output current
V
ESD Voltage
Machine Model(8)
Charge Device Model(9)
Corner Pins (Pins 1, 8, 9, 16, 17, 24, 25 and 32)
All other Pins (Pins 2-7, 10-15, 18-23, 26-31)
NC Pin Voltage (NC pins 11, 15, 16, 20, 21, 24, 28 and 30)(10)
V
A
V
Notes
5. Exceeding voltage limits on specified pins may cause a malfunction or permanent damage to the device.
6. Extended voltage range for programming purpose only.
7. Testing is performed in accordance with the Human Body Model (CZAP = 100pF, RZAP = 1500Ω),
8.
9.
10.
Testing is performed in accordance with the Machine Model (CZAP = 200pF, RZAP = 0Ω),
Testing is performed in accordance with the Charge Device Model, Robotic (CZAP = 4.0pF).
Special configuration recommended / mandatory for marked NC pins. Please refer to the typical application shown on page 41.
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
5
ELECTRICAL CHARACTERISTICS
MAXIMUM RATINGS
Table 2. Maximum Ratings (continued)
All voltages are with respect to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or
permanent damage to the device.
Ratings
Symbol
Value
Unit
THERMAL RATINGS
Operating Ambient Temperature(11)
°C
TA
33911
-40 to 125
34911
-40 to 85
TJ
-40 to 150
°C
Storage Temperature
TSTG
-55 to 150
°C
Thermal Resistance, Junction to Ambient
RθJA
Operating Junction Temperature
°C/W
Natural Convection, Single Layer board (1s)(12), (13)
85
Natural Convection, Four Layer board (2s2p)(12), (14)
56
(15)
Thermal Resistance, Junction to Case
Peak Package Reflow Temperature During
Reflow(16), (17)
RθJC
23
°C/W
TPPRT
Note 17
°C
Notes
11. The limiting factor is junction temperature; taking into account the power dissipation, thermal resistance, and heat sinking.
12.
Junction temperature is a function of on-chip power dissipation, package thermal resistance, mounting site (board) temperature, ambient
temperature, air flow, power dissipation of other components on the board, and board thermal resistance.
13.
14.
15.
16.
Per JEDEC JESD51-2 with the single layer board (JESD51-3) horizontal.
Per JEDEC JESD51-6 with the board (JESD51-7) horizontal.
Thermal resistance between the die and the case top surface as measured by the cold plate method (MIL SPEC-883 Method 1012.1).
Pin soldering temperature limit is for 10 seconds maximum duration. Not designed for immersion soldering. Exceeding these limits may
cause malfunction or permanent damage to the device.
Freescale’s Package Reflow capability meets Pb-free requirements for JEDEC standard J-STD-020C. For Peak Package Reflow
Temperature and Moisture Sensitivity Levels (MSL), Go to www.freescale.com, search by part number [e.g. remove prefixes/suffixes
and enter the core ID to view all orderable parts. (i.e. MC33xxxD enter 33xxx), and review parametrics.
17.
33911
6
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics
Characteristics noted under conditions 5.5V ≤ VSUP ≤ 18V, -40°C ≤ TA ≤ 125°C for the 33911 and -40°C ≤ TA ≤ 85°C for the
34911, unless otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal
conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
VSUP
5.5
–
18
V
Functional Operating Voltage(18)
VSUPOP
–
–
27
V
Load Dump
VSUPLD
–
–
40
V
IRUN
–
4.5
10
mA
–
48
80
–
58
90
–
27
35
–
37
48
ICYCLIC
–
10
–
VBATFAIL
1.5
3.0
3.9
VBATFAIL_HYS
–
0.9
–
Threshold (measured on VS1)
VSUV
5.55
6.0
6.6
Hysteresis (measured on VS1)
VSUV_HYS
–
1.0
–
Threshold (measured on VS1)
VSOV
19.25
20.5
Hysteresis (measured on VS1)
VSOV_HYS
18
–
1.0
–
SUPPLY VOLTAGE RANGE (VS1, VS2)
Nominal Operating Voltage
SUPPLY CURRENT RANGE (VSUP = 13.5V)
Normal Mode (IOUT at VDD = 10mA), LIN Recessive State(19)
Stop Mode, VDD ON with IOUT = 100µA, LIN Recessive State
(19), (20), (21)
ISTOP
5.5V < VSUP < 12V
VSUP = 13.5V
Sleep Mode, VDD OFF, LIN Recessive
State(19), (21)
ISLEEP
5.5V < VSUP < 12V
12V ≤ VSUP < 13.5V
Cyclic Sense Supply Current
Adder(22)
µA
µA
µA
SUPPLY UNDER/OVER VOLTAGE DETECTIONS
Power-On Reset (BATFAIL)(23)
Threshold (measured on VS1)
V
(22)
Hysteresis (measured on VS1)(22)
VSUP Under-voltage Detection (VSUV Flag) (Normal and Normal Request
Modes, Interrupt Generated)
V
VSUP Over-voltage Detection (VSOV Flag) (Normal and Normal Request
Modes, Interrupt Generated)
V
Notes
18. Device is fully functional. All features are operating.
19. Total current (IVS1 + IVS2) measured at GND pins excluding all loads, cyclic sense disabled.
20.
Total IDD current (including loads) below 100µA.
21.
Stop and Sleep Modes current will increase if VSUP exceeds 13.5V.
22.
23.
This parameter is guaranteed by process monitoring but not production tested.
The flag is set during power-up sequence. To clear the flag, a SPI read must be performed.
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
7
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics (continued)
Characteristics noted under conditions 5.5V ≤ VSUP ≤ 18V, -40°C ≤ TA ≤ 125°C for the 33911 and -40°C ≤ TA ≤ 85°C for the
34911, unless otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal
conditions, unless otherwise noted.
Characteristic
(24)
VOLTAGE REGULATOR
Symbol
Min
Typ
Max
4.75
5.00
5.25
60
110
200
–
0.1
0.25
Unit
(VDD)
Normal Mode Output Voltage
VDDRUN
1.0mA < IVDD < 50mA; 5.5V < VSUP < 27V
Normal Mode Output Current Limitation
IVDDRUN
Dropout Voltage(25)
VDDDROP
IVDD = 50mA
Stop Mode Output Voltage
V
V
VDDSTOP
IVDD < 5 mA
mA
V
4.75
5.0
5.25
IVDDSTOP
6.0
12
36
Normal Mode, 5.5V < VSUP < 18V; IVDD = 10mA
LRRUN
–
20
25
Stop Mode, 5.5V < VSUP < 18V; IVDD = 1.0mA
LRSTOP
–
5.0
25
Normal Mode, 1.0mA < IVDD < 50mA
LDRUN
–
15
80
Stop Mode, 0.1mA < IVDD < 5mA
LDSTOP
–
10
50
110
125
140
TPRE_HYS
–
10
–
°C
TSD
155
170
185
°C
TSD_HYS
–
10
–
°C
Stop Mode Output Current Limitation
Line Regulation
mV
Load Regulation
Over-temperature Prewarning
mA
mV
(Junction)(26)
TPRE
Interrupt generated, Bit VDDOT Set
Over-temperature Prewarning hysteresis(26)
Over-temperature Shutdown Temperature
(26)
Over-temperature Shutdown hysteresis
(Junction)(26)
°C
Notes
24. Specification with external capacitor 2µF < C < 100µF and 100mΩ ≤ ESR ≤ 10Ω.
25. Measured when voltage has dropped 250mV below its nominal Value (5V).
26. This parameter is guaranteed by process monitoring but not production tested.
33911
8
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics (continued)
Characteristics noted under conditions 5.5V ≤ VSUP ≤ 18V, -40°C ≤ TA ≤ 125°C for the 33911 and -40°C ≤ TA ≤ 85°C for the
34911, unless otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal
conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
VRSTTH
4.3
4.5
4.7
V
0.0
–
0.9
-150
-250
-350
1.5
–
8.0
RST INPUT/OUTPUT PIN (RST)
VDD Low-Voltage Reset Threshold
Low-state Output Voltage
VOL
IOUT = 1.5mA; 3.5V ≤ VSUP ≤ 27V
High-state Output Current (0 < VOUT < 3.5V)
Pull-down Current Limitation (internally limited)
IOH
V
IPD_MAX
VOUT = VDD
µA
mA
Low-state Input Voltage
VIL
-0.3
–
0.3 x VDD
V
High-state Input Voltage
VIH
0.7 x VDD
–
VDD +0.3
V
0.0
–
1.0
VDD -0.9
–
VDD
MISO SPI OUTPUT PIN (MISO)
Low-state Output Voltage
VOL
IOUT = 1.5mA
High-state Output Voltage
VOH
IOUT = -250µA
Tri-state Leakage Current
V
V
ITRIMISO
0V ≤ VMISO ≤ VDD
µA
-10
–
10
SPI INPUT PINS (MOSI, SCLK, CS)
Low-state Input Voltage
VIL
-0.3
–
0.3 x VDD
V
High-state Input Voltage
VIH
0.7 x VDD
–
VDD +0.3
V
MOSI, SCLK Input Current
IIN
0V ≤ VIN ≤ VDD
CS Pull-up Current
µA
-10
–
10
10
20
30
0.0
–
0.8
VDD -0.8
–
VDD
IPUCS
0V < VIN < 3.5V
µA
INTERRUPT OUTPUT PIN (IRQ)
Low-state Output Voltage
VOL
IOUT = 1.5mA
High-state Output Voltage
VOH
IOUT = -250µA
Leakage Current
V
V
VOH
VDD ≤ VOUT ≤ 10V
mA
–
–
2.0
PULSE WIDTH MODULATION INPUT PIN (PWMIN)
Low-state Input Voltage
VIL
-0.3
–
0.3 x VDD
V
High-state Input Voltage
VIH
0.7 x VDD
–
VDD +0.3
V
10
20
30
Pull-up current
0V < VIN < 3.5V
IPUPWMIN
µA
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
9
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics (continued)
Characteristics noted under conditions 5.5V ≤ VSUP ≤ 18V, -40°C ≤ TA ≤ 125°C for the 33911 and -40°C ≤ TA ≤ 85°C for the
34911, unless otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal
conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
TJ = 25°C, ILOAD = 50mA; VSUP > 9.0V
–
–
7.0
TJ = 150°C, ILOAD = 50mA; VSUP > 9.0V(27)
–
–
10
TJ = 150°C, ILOAD = 30mA; 5.5V < VSUP < 9.0V(27)
–
–
14
Unit
HIGH SIDE OUTPUT HS1 PIN (HS1)
Output Drain-to-Source On resistance
Ω
RDS(ON)
Output Current Limitation(28)
ILIMHS1
0V < VOUT < VSUP - 2.0V
mA
60
120
250
–
5.0
7.5
–
–
10
VSUP -2
–
–
THSSD
150
165
180
°C
THSSD_HYS
–
10
–
°C
TJ = 25°C, ILOAD = 150mA, VSUP > 9.0V
–
–
2.5
TJ = 125°C, ILOAD = 150mA, VSUP > 9.0V
–
–
4.5
TJ = 125°C, ILOAD = 120mA, 5.5V < VSUP < 9.0V
–
–
10
160
275
350
–
8.0
12
Open Load Current Detection
(29)
IOLHS1
Leakage Current
ILEAK
-0.2V < VHS1 < VS2 + 0.2V
Short-circuit Detection Threshold(30)
Over-temperature Shutdown(31), (36)
Over-temperature Shutdown
µA
VTHSC
5.5V < VSUP < 27V
Hysteresis(36)
mA
V
LOW SIDE OUTPUTS LS1 AND LS2 PINS (LS1, LS2)
Output Drain-to-Source On resistance
Ω
RDS(ON)
Output Current Limitation (32)
ILIMLSX
2.0V < VOUT < VSUP
Open Load Current Detection(33)
IOLLSX
Leakage Current
ILEAK
-0.2V < VOUT < VS1
Active Output Energy Clamp
mA
µA
–
–
10
VSUP +2
–
VSUP +5
2.0
–
–
TLSSD
150
165
180
°C
TLSSD_HYS
–
10
–
°C
VCLAMP
IOUT = 150mA
Short-circuit Detection Threshold(34)
V
VTHSC
5.5V < VSUP < 27V
Over-temperature Shutdown(35), (36)
(36)
Over-temperature Shutdown Hysteresis
mA
V
Notes
27. This parameter is production tested up to TA = 125°C and guaranteed by process monitoring up to TJ = 150°C.
28.
29.
30.
31.
32.
33.
34.
35.
36.
When over-current occurs, the High Side stays ON with limited current capability and the HS1CL flag is set in the HSSR.
When open Load occurs, the flag (HS1OP) is set in the HSSR.
When short-circuit occurs and if the HVSE flag is enabled, HS1 automatically shut down.
When over-temperature Shutdown occurs, the High Side is turned off. All flags in HSSR are set.
When over-current occurs, the corresponding Low Side stays ON with limited current capability and the LSxCL flag is set in the LSSR.
When open load occurs, the flag (LSxOP) is set in the LSSR.
When short-circuit occurs and if the HVSE flag is enabled, both LS automatically shut down.
When over-temperature shutdown occurs, both Low Sides are turned off. All flags in LSSR are set.
Guaranteed by characterization but not production tested
33911
10
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics (continued)
Characteristics noted under conditions 5.5V ≤ VSUP ≤ 18V, -40°C ≤ TA ≤ 125°C for the 33911 and -40°C ≤ TA ≤ 85°C for the
34911, unless otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal
conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
2.0
2.5
3.0
3.0
3.5
4.0
0.5
1.0
1.5
-10
–
10
800
1550
–
LXDS (Lx Divider Select) = 0
0.95
1.0
1.05
LXDS (Lx Divider Select) = 1
3.42
3.6
3.78
-80
0.0
80
-22
0.0
22
Unit
L1 AND L2 INPUT PINS (L1, L2)
Low Detection Threshold
VTHL
5.5V < VSUP < 27V
High Detection Threshold
VTHH
5.5V < VSUP < 27V
Hysteresis
Analog Input Divider Ratio (RATIOLx = VLx / VADOUT0)
Analog Output offset Ratio
LXDS (Lx Divider Select) = 0
RLxIN
µA
kΩ
RATIOLx
VRATIOLxOFFSET
LXDS (Lx Divider Select) = 1
Analog Inputs Matching
V
IIN
-0.2V < VIN < VS1
Analog Input Impedance(38)
V
VHYS
5.5V < VSUP < 27V
Input Current(37)
V
mV
LxMATCHING
%
LXDS (Lx Divider Select) = 0
96
100
104
LXDS (Lx Divider Select) = 1
96
100
104
REXT
20
–
200
kΩ
WDACC
-15
–
15
%
STTOV
–
10.5
–
mV/K
5.0
5.25
5.5
-30
–
30
-45
–
45
WINDOW WATCHDOG CONFIGURATION PIN (WDCONF)
External Resistor Range
Watchdog Period Accuracy with External Resistor (Excluding Resistor
Accuracy)(39)
ANALOG MULTIPLEXER
Internal Chip Temperature Sense Gain
VSENSE Input Divider Ratio (RATIOVSENSE = VVSENSE / VADOUT0)
RATIOVSENSE
5.5V < VSUP < 27V
VSENSE Output Related Offset
OFFSETVSENSE
-40°C < TA < -20°C
mV
ANALOG OUTPUT (ADOUT0)
Maximum Output Voltage
VOUT_MAX
-5mA < IO < 5mA
Minimum Output Voltage
-5mA < IO < 5mA
V
VDD -0.35
–
VDD
0.0
–
0.35
VOUT_MIN
V
Notes
37. Analog Multiplexer input disconnected from Lx input pin.
38. Analog Multiplexer input connected to Lx input pin.
39. Watchdog timing period calculation formula: tPWD [ms] = 0.466 * (REXT - 20) + 10 (REXT in kΩ)
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
11
ELECTRICAL CHARACTERISTICS
STATIC ELECTRICAL CHARACTERISTICS
Table 3. Static Electrical Characteristics (continued)
Characteristics noted under conditions 5.5V ≤ VSUP ≤ 18V, -40°C ≤ TA ≤ 125°C for the 33911 and -40°C ≤ TA ≤ 85°C for the
34911, unless otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal
conditions, unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
0.0
–
0.8
VDD -0.8
–
VDD
Unit
RXD OUTPUT PIN (LIN PHYSICAL LAYER) (RXD)
Low-state Output Voltage
VOL
IOUT = 1.5mA
High-state Output Voltage
V
VOH
IOUT = -250µA
V
TXD INPUT PIN (LIN PHYSICAL LAYER) (TXD)
Low-state Input Voltage
VIL
-0.3
–
0.3 x VDD
V
High-state Input Voltage
VIH
0.7 x VDD
–
VDD +0.3
V
IPUIN
10
20
30
µA
40
120
200
Pin Pull-up Current, 0V < VIN < 3.5V
LIN PHYSICAL LAYER, TRANSCEIVER (LIN)(40)
Output Current Limitation
IBUSLIM
Dominant State, VBUS = 18V
mA
Leakage Output Current to GND
Dominant State; VBUS = 0V; VBAT = 12V
IBUS_PAS_DOM
-1.0
–
–
mA
Recessive State; 8V < VBAT < 18V; 8V < VBUS < 18V; VBUS ≥ VBAT
IBUS_PAS_REC
IBUS_NO_GND
–
-1.0
–
–
20
1.0
µA
mA
IBUS
–
–
100
µA
GND Disconnected; GNDDEVICE = VSUP; VBAT = 12V; 0V < VBUS < 18V
VBAT Disconnected; VSUP_DEVICE = GND; 0V < VBUS < 18V
Receiver Input Voltages
VSUP
Receiver Dominant State
VBUSDOM
–
–
Receiver Recessive State
VBUSREC
0.6
–
–
Receiver Threshold Center (VTH_DOM + VTH_REC)/2
VBUS_CNT
0.475
0.5
0.525
Receiver Threshold Hysteresis (VTH_REC - VTH_DOM)
VHYS
–
–
0.175
VLIN_REC
VSUP-1
–
–
Dominant State, TXD LOW, 500Ω External Pull-up Resistor, LDVS = 0
VLIN_DOM_0
–
1.1
1.4
Dominant State, TXD LOW, 500Ω External Pull-up Resistor, LDVS = 1
VLIN_DOM_1
–
1.7
2
RSLAVE
20
30
60
kΩ
TLINSD
150
165
180
°C
TLINSD_HYS
–
10
–
°C
0.4
LIN Transceiver Output Voltage
Recessive State, TXD HIGH, IOUT = 1.0 µA
LIN Pull-up Resistor to VSUP
Over-temperature
Shutdown(41)
Over-temperature Shutdown Hysteresis
V
Notes
40. Parameters guaranteed for 7.0V ≤ VSUP ≤ 18V.
41.
When over-temperature shutdown occurs, the LIN bus goes into a recessive state and the flag LINOT in the LINSR is set.
33911
12
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 4. Dynamic Electrical Characteristics
Characteristics noted under conditions 5.5V ≤ VSUP ≤ 18V, -40°C ≤ TA ≤ 125°C for the 33911 and -40°C ≤ TA ≤ 85°C for the
34911, otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal conditions,
unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
SPI Operating Frequency
f SPIOP
–
–
4.0
MHz
SCLK Clock Period
SPI INTERFACE TIMING (see Figure 13, page 19)
tPSCLK
250
–
N/A
ns
SCLK Clock High Time(42)
tWSCLKH
110
–
N/A
ns
SCLK Clock Low Time(42)
tWSCLKL
110
–
N/A
ns
Falling Edge of CS to Rising Edge of SCLK(42)
tLEAD
100
–
N/A
ns
Falling Edge of SCLK to CS Rising Edge(42)
tLAG
100
–
N/A
ns
MOSI to Falling Edge of SCLK(42)
tSISU
40
–
N/A
ns
Falling Edge of SCLK to MOSI(42)
tSIH
40
–
N/A
ns
MISO Rise Time(42)
tRSO
–
40
–
CL = 220pF
MISO Fall Time(42)
tFSO
CL = 220pF
Time from Falling or Rising Edges of
ns
ns
–
40
–
CS to:(42)
ns
- MISO Low-impedance
tSOEN
0.0
–
50
- MISO High -impedance
tSODIS
0.0
–
50
Time from Rising Edge of SCLK to MISO Data Valid(42)
tVALID
0.0
–
75
t RST
0.65
1.0
1.35
ms
t RSTDF
350
600
900
ns
8.5
10
11.5
0.2 x VDD ≤ MISO ≥ 0.8 x VDD, CL = 100pF
ns
RST OUTPUT PIN
Reset Low-Level Duration after VDD High (see Figure 12, page 19)
Reset Deglitch Filter Time
WINDOW WATCHDOG CONFIGURATION PIN (WDCONF)
Watchdog Time Period (43)
External Resistor REXT = 20kΩ (1%)
t PWD
ms
External Resistor REXT = 200kΩ (1%)
79
94
108
Without External Resistor REXT (WDCONF pin open)
110
150
205
Notes
42. This parameter is guaranteed by process monitoring but not production tested.
43. Watchdog timing period calculation formula: tPWD [ms] = 0.466 * (REXT - 20) + 10 (REXT in kΩ)
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
13
ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 4. Dynamic Electrical Characteristics (continued)
Characteristics noted under conditions 5.5V ≤ VSUP ≤ 18V, -40°C ≤ TA ≤ 125°C for the 33911 and -40°C ≤ TA ≤ 85°C for the
34911, otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal conditions,
unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
t WUF
8.0
20
38
µs
–
–
5.0
110
150
205
–
–
10
L1 AND L2 INPUTS
Wake-Up Filter Time
STATE MACHINE TIMING
Delay Between CS LOW-to-HIGH Transition (at the End of a SPI Stop
Command) and Stop Mode Activation(44)
Normal Request Mode Timeout (see Figure 12, page 19)
Delay Between SPI Command and HS /LS Turn On(45)
t NR TOUT
Delay Between Normal Request and Normal Mode After a Watchdog Trigger
Command (Normal Request Mode)(44)
µs
t S-OFF
9V < VSUP < 27V
–
–
10
–
–
10
µs
t SNR2N
µs
Delay Between CS Wake-Up (CS LOW to HIGH) in Stop Mode and:
Normal Request Mode, VDD ON and RST HIGH
t WUCS
9.0
15
80
First Accepted SPI Command
t WUSPI
90
—
N/A
t 2CS
4.0
—
—
Minimum Time Between Rising and Falling Edge on the CS
ms
µs
t S-ON
9V < VSUP < 27V
Delay Between SPI Command and HS /LS Turn Off(45)
µs
t STOP
µs
LIN PHYSICAL LAYER: DRIVER CHARACTERISTICS FOR NORMAL SLEW RATE - 20.0KBIT/SEC(46), (47)
Duty Cycle 1: D1 = tBUS_REC(MIN)/(2 x tBIT), tBIT = 50µs
7.0V ≤ VSUP ≤ 18V
Duty Cycle 2: D2 = tBUS_REC(MAX)/(2 x tBIT), tBIT = 50µs
7.6V ≤ VSUP ≤ 18V
LIN PHYSICAL LAYER: DRIVER CHARACTERISTICS FOR SLOW SLEW RATE Duty Cycle 3: D3 = tBUS_REC(MIN)/(2 x tBIT), tBIT = 96µs
7.0V ≤ VSUP ≤ 18V
Duty Cycle 4: D4 = tBUS_REC(MAX)/(2 x tBIT), tBIT = 96µs
7.6V ≤ VSUP ≤ 18V
D1
0.396
—
—
—
—
0.581
D2
10.4KBIT/SEC(46), (48)
µs
D3
0.417
—
—
—
—
0.590
µs
D4
Notes
44. This parameter is guaranteed by process monitoring but not production tested.
45. Delay between turn on or off command (rising edge on CS) and HS or LS ON or OFF, excluding rise or fall time due to an external load.
46. Bus load RBUS and CBUS 1.0nF / 1.0kΩ, 6.8nF / 660Ω, 10nF / 500Ω. Measurement thresholds: 50% of TXD signal to LIN signal threshold
defined at each parameter. See Figure 6, page 17.
47. See Figure 7, page 17.
48. See Figure 8, page 17.
33911
14
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
DYNAMIC ELECTRICAL CHARACTERISTICS
Table 4. Dynamic Electrical Characteristics (continued)
Characteristics noted under conditions 5.5V ≤ VSUP ≤ 18V, -40°C ≤ TA ≤ 125°C for the 33911 and -40°C ≤ TA ≤ 85°C for the
34911, otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25°C under nominal conditions,
unless otherwise noted.
Characteristic
Symbol
Min
Typ
Max
Unit
SRFAST
—
20
—
V / µs
t REC_PD
—
3.0
6.0
t REC_SYM
- 2.0
—
2.0
t PROPWL
42
70
95
t WAKE
—
—
1500
t WAKE
9.0
13
17
t TXDDOM
0.65
1.0
1.35
LIN PHYSICAL LAYER: DRIVER CHARACTERISTICS FOR FAST SLEW RATE
LIN Fast Slew Rate (Programming Mode)
LIN PHYSICAL LAYER: CHARACTERISTICS AND WAKE-UP TIMINGS
(49)
Propagation Delay and Symmetry(50)
µs
Propagation Delay Receiver, tREC_PD = max (tREC_PDR, tREC_PDF)
Symmetry of Receiver Propagation Delay tREC_PDF - tREC_PDR
Bus Wake-up Deglitcher (Sleep and Stop
Modes)(51)
µs
Bus Wake-up Event Reported
From Sleep Mode
(52)
From Stop Mode(53)
TXD Permanent Dominant State Delay
µs
s
PULSE WIDTH MODULATION INPUT PIN (PWMIN)
PWMIN pin(54)
Max. frequency to drive HS and LS output pins
fPWMIN
kHz
10
Notes
49. VSUP from 7.0V to 18V, bus load RBUS and CBUS 1.0nF / 1.0kΩ, 6.8nF / 660Ω, 10nF / 500Ω. Measurement thresholds: 50% of TXD
signal to LIN signal threshold defined at each parameter. See Figure 6, page 17.
50. See Figure 9, page 18
51. See Figure 10, page 18 for Sleep and Figure 11, page 18 for Stop Mode.
52. The measurement is done with 1µF capacitor and 0mA current load on VDD. The value takes into account the delay to charge the
capacitor. The delay is measured between the bus wake-up threshold (VBUSWU) rising edge of the LIN bus and when VDD reaches 3.0V.
See Figure 10, page 18. The delay depends of the load and capacitor on VDD.
53.
54.
In Stop Mode, the delay is measured between the bus wake-up threshold (VBUSWU) and the falling edge of the IRQ pin. See Figure 11,
page 18.
This parameter is guaranteed by process monitoring but not production tested.
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
15
ELECTRICAL CHARACTERISTICS
TIMING DIAGRAMS
TIMING DIAGRAMS
33911
1.0nF
LIN
TRANSIENT PULSE
GENERATOR
(NOTE)
GND
PGND LGND
AGND
Note Waveform per ISO 7637-2. Test Pulses 1, 2, 3a, 3b.
Figure 4. Test Circuit for Transient Test Pulses (LIN)
33911
1.0nF
L1, L2
TRANSIENT PULSE
GENERATOR
(NOTE)
10kΩ
GND
PGND LGND
AGND
NOTE: Waveform per ISO 7637-2. Test Pulses 1, 2, 3a, 3b.
Figure 5. Test Circuit for Transient Test Pulses (Lx)
VSUP
R0
TXD
LIN
RXD
C0
R0 AND C0 COMBINATIONS:
• 1.0KΩ and 1.0nF
• 660Ω and 6.8nF
• 500Ω and 10nF
Figure 6. Test Circuit for LIN Timing Measurements
33911
16
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
TIMING DIAGRAMS
TXD
tBIT
tBIT
tBUS_DOM (MAX)
VLIN_REC
tBUS_REC (MIN)
tREC - MAX
tDOM - MIN
58.1% VSUP
40.0% VSUP
LIN
tDOM - MIN
74.4% VSUP
60.0% VSUP
58.1% VSUP
40.0% VSUP
28.4% VSUP
28.4% VSUP
42.2% VSUP
tREC - MIN
tDOM - MAX
tBUS_DOM (MIN)
tBUS_REC (MAX)
RXD
tRDOM
tRREC
Figure 7. LIN Timing Measurements for Normal Slew Rate
TXD
tBIT
tBIT
tBUS_DOM (MAX)
VLIN_REC
tBUS_REC (MIN)
tREC - MAX
tDOM - MIN
61.6% VSUP
40.0% VSUP
LIN
tDOM - MIN
77.8% VSUP
60.0% VSUP
61.6% VSUP
40.0% VSUP
25.1% VSUP
25.1% VSUP
38.9% VSUP
tREC - MIN
tDOM - MAX
tBUS_DOM (MIN)
tBUS_REC (MAX)
RXD
tRDOM
tRREC
Figure 8. LIN Timing Measurements for Slow Slew Rate
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
17
ELECTRICAL CHARACTERISTICS
TIMING DIAGRAMS
VLIN_REC
VBUSrec
VBUSdom
VSUP
LIN BUS SIGNAL
RXD
tRX_PDF
tRX_PDR
Figure 9. LIN Receiver Timing
VLIN_REC
LIN
0.4 VSUP
DOMINANT LEVEL
VDD
tPROPWL
tWAKE
Figure 10. LIN Wake-Up Sleep Mode Timing
Vrec
VLIN_REC
LIN
0.4VSUP
0.4 VSUP
Dominant
Level
Dominant level
IRQ
t PROPWL
TpropWL
t WAKE
Twake
Figure 11. LIN Wake-Up Stop Mode Timing
33911
18
Analog Integrated Circuit Device Data
Freescale Semiconductor
ELECTRICAL CHARACTERISTICS
TIMING DIAGRAMS
VSUP
VDD
RST
tNRTOUT
tRST
Figure 12. Power On Reset and Normal Request timeout Timing
tPSCLK
CS
tWSCLKH
tLEAD
tLAG
SCLK
tWSCLKL
tSISU
MOSI
UNDEFINED
D0
tSIH
DON’T CARE
D7
DON’T CARE
tVALID
tSODIS
tSOEN
MISO
D0
DON’T CARE
D7
Figure 13. SPI Timing Characteristics
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
19
FUNCTIONAL DESCRIPTION
INTRODUCTION
FUNCTIONAL DESCRIPTION
INTRODUCTION
The 33911 was designed and developed as a highly
integrated and cost-effective solution for automotive and
industrial applications. For automotive body electronics, the
33911 is well suited to perform relay control in applications
like window lift, sunroof, etc. via a LIN bus.
Power switches are provided on the device configured as
high side and low side outputs. Other ports are also provided,
which include a voltage sense port and two wake-up capable
pins. An internal voltage regulator provides power to a MCU
device.
Also included in this device is a LIN physical layer, which
communicates using a single wire. This enables this device
to be compatible with 3-wire bus systems, where one wire is
used for communication, one for battery, and one for ground.
FUNCTIONAL PIN DESCRIPTION
See Figure 1, 33911 Simplified Application Diagram,
page 1, for a graphic representation of the various pins
referred to in the following paragraphs. Also, see the pin
diagram on page 3 for a description of the pin locations in the
package.
RECEIVER OUTPUT (RXD)
The RXD pin is a digital output. It is the receiver output of
the LIN interface and reports the state of the bus voltage:
RXD Low when LIN bus is dominant, RXD High when LIN bus
is recessive.
TRANSMITTER INPUT (TXD)
The TXD pin is a digital input. It is the transmitter input of
the LIN interface and controls the state of the bus output
(dominant when TXD is Low, recessive when TXD is High).
This pin has an internal pull-up to force recessive state in
case the input is left floating.
microcontroller. Data on this output pin changes on the
negative edge of the SCLK. When CS is High, this pin will
remain in high-impedance state.
CHIP SELECT (CS)
CS is an active low digital input. It must remain low during
a valid SPI communication and allow for several devices to
be connected in the same SPI bus without contention. A
rising edge on CS signals the end of the transmission and the
moment the data shifted in is latched. A valid transmission
must consist of 8 bits only.
While in STOP Mode a low-to-high level transition on this
pin will generate a wake-up condition.
ANALOG MULTIPLEXER (ADOUT0)
The ADOUT0 pin can be configured via the SPI to allow
the MCU A/D converter to read the several inputs of the
Analog Multiplexer, including the VSENSE, L1, L2 input
voltages and the internal junction temperature.
LIN BUS (LIN)
The LIN pin represents the single-wire bus transmitter and
receiver. It is suited for automotive bus systems and is
compliant to the LIN bus specification 2.0.
The LIN interface is only active during Normal and Normal
Request Modes.
SERIAL DATA CLOCK (SCLK)
The SCLK pin is the SPI clock input pin. MISO data
changes on the negative transition of the SCLK. MOSI is
sampled on the positive edge of the SCLK.
MASTER OUT SLAVE IN (MOSI)
The MOSI digital pin receives SPI data from the MCU. This
data input is sampled on the positive edge of SCLK.
MASTER IN SLAVE OUT (MISO)
The MISO pin sends data to a SPI-enabled MCU. It is a
digital tri-state output used to shift serial data to the
PWM INPUT CONTROL (PWMIN)
This digital input can control the high side and low side
drivers in Normal Request and Normal Mode.
To enable PWM control, the MCU must perform a write
operation to the High Side Control Register (HSCR), or the
Low Side Control Register (LSCR).
This pin has an internal 20µA current pull-up.
RESET (RST)
This bidirectional pin is used to reset the MCU in case the
33911 detects a reset condition, or to inform the 33911 that
the MCU was just reset. After release of the RST pin Normal
Request Mode is entered.
The RST pin is an active low filtered input and output
formed by a weak pull-up and a switchable pull-down
structure, which allows this pin to be shorted either to VDD or
to GND during software development without the risk of
destroying the driver.
33911
20
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DESCRIPTION
FUNCTIONAL PIN DESCRIPTION
INTERRUPT (IRQ)
The IRQ pin is a digital output used to signal events or
faults to the MCU while in Normal and Normal Request Mode
or to signal a wake-up from Stop Mode. This active low output
will transition high only after the interrupt is acknowledged by
a SPI read of the respective status bits.
WATCHDOG CONFIGURATION (WDCONF)
The WDCONF pin is the configuration pin for the internal
watchdog. A resistor can be connected to this pin to configure
the window watchdog period. When connected directly to
ground, the watchdog will be disabled. When this pin is left
open, the watchdog period is fixed to its lower precision
internal default value (150ms, typical).
GROUND CONNECTIONS (AGND, PGND, LGND)
The AGND, PGND and LGND pins are the Analog and
Power ground pins.
The AGND pin is the ground reference of the voltage
regulator.
The PGND and LGND pins are used for high-current load
return as in the relay-drivers and LIN interface pin.
Note: PGND, AGND and LGND pins must be connected
together.
LOW SIDES (LS1 AND LS2)
LS1 and LS2 are the low side driver outputs. Those
outputs are short-circuit protected and include active clamp
circuitry to drive inductive loads. Due to the energy clamp
voltage on this pin, it can raise above the battery level when
switched off. The switches are controlled through the SPI and
can be configured to respond to a signal applied to the
PWMIN input pin.
Both low side switches are protected against overheating.
DIGITAL/ANALOGS (L1 AND L2)
The Lx pins are multi purpose inputs. They can be used as
digital inputs, which can be sampled by reading the SPI and
used for wake-up when 33911 is in low-power mode or used
as analog inputs for the analog multiplexer. When used to
sense voltage outside the module, a 33kohm series resistor
must be used on each input.
When used as wake-up inputs L1 and L2 can be
configured to operate in cyclic sense mode. In this mode, the
high side switch is configured to be periodically turned on and
sample the wake-up inputs. If a state change is detected
between two cycles, a wake-up is initiated. The 33911 can
also wake-up from Stop or Sleep by a simple state change on
L1 and L2.
When used as an analog input, the voltage present on the
Lx pins are scaled down by a selectable internal voltage
divider and can be routed to the ADOUT0 output through the
analog multiplexer.
Note: If an Lx input is selected in the analog multiplexer, it
will be disabled as a digital input and remains disabled in lowpower mode. No wake-up feature is available in that
condition.
When an Lx input is not selected in the analog multiplexer,
the voltage divider is disconnected from that input.
HIGH SIDE OUTPUT (HS1)
This high side switch is able to drive loads such as relays
or lamps. Its structure is connected to the VS2 supply pin.
The pin is short-circuit protected and also protected against
overheating.
HS1 is controlled by SPI and can respond to a signal
applied to the PWMIN input pin.
The HS1 output can also be used during low-power mode
for the cyclic-sense of the wake inputs.
POWER SUPPLIES (VS1 AND VS2)
These are the battery level voltage supply pins. In
application, VS1 and VS2 pins must be protected against a
reverse battery connection and negative transient voltages
with external components. These pins sustain standard
automotive voltage conditions such as a load dump at 40V.
The high side switch (HS1) is supplied by the VS2 pin, all
other internal blocks are supplied by the VS1 pin.
VOLTAGE SENSE (VSENSE)
This input can be connected directly to the battery line. It
is protected against a battery reverse connection. The
voltage present on this input is scaled down by an internal
voltage divider, and can be routed to the ADOUT0 output pin
and used by the MCU to read the battery voltage.
The ESD structure on this pin allows for excursion up to
+40V and down to -27V, allowing this pin to be connected
directly to the battery line. It is strongly recommended to
connect a 10kohm resistor in series with this pin for protection
purposes.
+5V MAIN REGULATOR OUTPUT (VDD)
An external capacitor must be placed on the VDD pin to
stabilize the regulated output voltage. The VDD pin is
intended to supply a microcontroller. The pin is current limited
against shorts to GND and over-temperature protected.
During Stop Mode, the voltage regulator does not operate
with its full drive capabilities and the output current is limited.
During Sleep Mode the regulator output is completely shut
down.
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
21
FUNCTIONAL DESCRIPTION
FUNCTIONAL INTERNAL BLOCK DESCRIPTION
FUNCTIONAL INTERNAL BLOCK DESCRIPTION
MC33911 - Functional Block Diagram
Integrated Supply
Voltage Regulator VDD
Analog Circuitry
Window Watchdog
Wake-Up
High Side Driver
HS1
Digital / Analog Input
Voltage & Temperature Sense
Low Side Drivers
LS1 - LS2
MCU Interface and Output Control
LIN Physical Layer
Interface
SPI Interface
LIN Interface / Control
Reset & IRQ Logic
LS/HS - PWM Control
Analog Output 0
Integrated Supply
Analog Circuitry
MCU Interface and Output Control
Drivers
Figure 14. Functional Internal Block Diagram
ANALOG CIRCUITRY
MCU INTERFACE
The 33911 is designed to operate under automotive
operating conditions. A fully configurable window watchdog
circuit will reset the connected MCU in case of an overflow.
Two low-power modes are available with several different
wake-up sources to reactivate the device. Two analog / digital
inputs can be sensed or used as the wake-up source.
The device is capable of sensing the supply voltage
(VSENSE), the internal chip temperature (CTEMP) as well as
the motor current using an external sense resistor.)
The 33911 is providing its control and status information
through a standard 8-Bit SPI interface. Critical system events
such as low or high-voltage/temperature conditions as well as
over-current conditions in any of the driver stages can be
reported to the connected MCU via IRQ or RST.
Both low side and both high side driver outputs can be
controlled via the SPI register as well as PWMIN input.
HIGH SIDE DRIVER
One current and temperature protected high side driver
with PWM capability is provided to drive small loads such as
status LED’s or small lamps.
The driver can be configured for periodic sense during lowpower modes.
LOW SIDE DRIVERS
Two current and temperature protected low side
drivers with PWM capability are provided to drive HBridge type relays for power motor applications.
The integrated LIN physical layer interface can be
configured via the SPI register and its communication is
driven through the RXD and TXD device pin.
All internal analog sources are multiplexed to the ANOUT0
pin.
VOLTAGE REGULATOR OUTPUTS
One voltage regulators is implemented on the 33911. The
VDD main regulator output is designed to supply an MCU
with a precise 5V.
LIN PHYSICAL LAYER INTERFACE
The 33911 provides a LIN 2.0 compatible LIN physical
layer interface with selectable slew rate and various
diagnostic features.
33911
22
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATIONS
OPERATIONAL MODES
FUNCTIONAL DEVICE OPERATIONS
OPERATIONAL MODES
INTRODUCTION
The 33911 offers three main operating modes: Normal
(Run), Stop, and Sleep (Low-power). In Normal Mode, the
device is active and operating under normal application
conditions. The Stop and Sleep Modes are low-power modes
with wake-up capabilities.
In Stop Mode, the voltage regulator still supplies the MCU
with VDD (limited current capability), and in Sleep Mode the
voltage regulator is turned off (VDD = 0V).
Wake-up from Stop Mode is initiated by a wake-up
interrupt. Wake-up from Sleep Mode is done by a reset and
the voltage regulator is turned back on.
The selection of the different modes is controlled by the
MOD1:2 bits in the Mode Control Register (MCR).
Figure 15 describes how transitions are done between the
different operating modes, and Table 5, 25, gives an
overview of the operating modes.
RESET MODE
The 33911 enters the Reset Mode after a power up. In this
mode, the RST pin is low for 1ms (typical value). After this
delay, the 33911 enters the Normal Request Mode and the
RST pin is driven high.
The Reset Mode is entered if a reset condition occurs (VDD
low, Watchdog trigger fail, after a wake-up from Sleep Mode,
or a Normal Request Mode timeout).
NORMAL REQUEST MODE
This is a temporary mode automatically accessed by the
device after the Reset Mode, or after a wake-up from Stop
Mode.
In Normal Request Mode, the VDD regulator is ON, the
Reset pin is high and the LIN is operating in RX Only Mode.
As soon as the device enters the Normal Request Mode,
an internal timer is started for 150ms (typical value). During
these 150ms, the MCU must configure the Timing Control
Register (TIMCR) and the MCR with MOD2 and MOD1 bits
set = 0, to enter in Normal Mode. If within the 150ms timeout
the MCU does not command the 33911 to Normal Mode, it
will enter in Reset Mode. If the WDCONF pin is grounded in
order to disable the watchdog function, the 33911 goes
directly in Normal Mode after the Reset Mode. If the
WDCONF pin is open, the 33911 stays typically for 150ms in
Normal Request before entering in Normal Mode.
The VDD regulator is ON and delivers its full current
capability.
If an external resistor is connected between the WDCONF
pin and the Ground, the window watchdog function will be
enabled.
The wake-up inputs (L1 and L2) can be read as digital
inputs or have its voltage routed through the analog
multiplexer.
The LIN interface has slew rate and timing compatible with
the LIN protocol specification 2.0. The LIN bus can transmit
and receive information.
The high side and the low side switches are active and
have PWM capability according to the SPI configuration.
The interrupts are generated to report failures for VSUP
over/under-voltage, thermal shutdown or thermal shutdown
prewarning on the main regulator.
SLEEP MODE
The Sleep Mode is a low-power mode. From Normal
Mode, the device enters the Sleep Mode by sending one SPI
command through the MCR. All blocks are in their lowest
power consumption condition. Only some wake-up sources
(wake-up inputs with or without cyclic sense, forced wake-up,
and LIN receiver) are active. The 5V regulator is OFF. The
internal low-power oscillator may be active if the IC is
configured for cyclic sense. In this condition, the high side
switches are turned on periodically and the wake-up inputs
are sampled.
Wake-up from Sleep Mode is similar to a power-up. The
device goes into Reset Mode except that the SPI will report
the wake-up source, and the BATFAIL flag is not set.
STOP MODE
The Stop Mode is the second low-power mode, but in this
case the 5V regulator is ON with limited current drive
capability. The application MCU is always supplied while the
33911 is operating in Stop Mode.
The device can enter the Stop Mode only by sending a SPI
command. When the application is in this mode, it can wakeup from the 33911 side (for example: cyclic sense, force
wake-up, LIN bus, wake inputs) or the MCU side (CS, RST
pins). Wake-up from Stop Mode will transition the 33911 to
Normal Request Mode and generate an interrupt, except if
the wake-up event is a low to high transition on the CS pin or
comes from the RST pin.
NORMAL MODE
In Normal Mode, all 33911 functions are active and can be
controlled by the SPI interface and the PWMIN pin.
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
23
FUNCTIONAL DEVICE OPERATIONS
OPERATIONAL MODES
Normal Request Timeout Expired (t NRTOUT)
VDD LOW
NORMAL
REQUEST
VDD LOW
VDD LOW (>t NRTOUT) EXPIRED
AND VSUV = 0
SLEEP COMMAND
STOP COMMAND
NORMAL
WD FAILED
WAKE-UP (INTERRUPT)
RESET
VDD HIGH AND
RESET DELAY (t RST) EXPIRED
WD DISABLED
Power Up
WD TRIGGER
POWER
DOWN
WAKE-UP (RESET)
SLEEP
STOP
VDD LOW
Legend
WD: Watchdog
WD Disabled: Watchdog disabled (WDCONF pin connected to GND)
WD Trigger: Watchdog is triggered by SPI command
WD Failed: No watchdog trigger or trigger occurs in closed window
Stop Command: Stop command sent via SPI
Sleep Command: Sleep command sent via SPI
wake-up from Stop Mode: Lx state change, LIN bus wake-up, Periodic wake-up, CS rising edge wake-up or RST wake-up.
wake-up from Sleep Mode: Lx state change, LIN bus wake-up, Periodic wake-up.
Figure 15. Operating Modes and Transitions
33911
24
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATIONS
OPERATIONAL MODES
Table 5. Operating Modes Overview
Function
VDD
LSx
Reset Mode Normal Request Mode
Full
Normal
Mode
Stop Mode
Sleep Mode
Full
Stop
-
Full
(55)
-
SPI/PWM
SPI/PWM
-
-
HS1
-
SPI/PWM(55)
SPI/PWM
Note(56)
Note(57)
Analog Mux
-
SPI
SPI
-
-
Lx
-
Inputs
Inputs
Wake-up
Wake-up
LIN
-
Rx-Only
full/Rx-Only
Rx-Only/Wake-up
Wake-up
-
-
VDD
-
Watchdog
-
150ms (typ.) timeout
VSENSE
On
On
Notes
55.
56.
57.
58.
On
(58)/Off
On
Operation can be controlled by the PWMIN input.
HS switch can be configured for cyclic sense operation in Stop Mode.
HS switch can be configured for cyclic sense operation in Sleep Mode.
Windowing operation when enabled by an external resistor.
INTERRUPTS
High-voltage Interrupt
Interrupts are used to signal a microcontroller that a
peripheral needs to be serviced. The interrupts which can be
generated change according to the operating mode. While in
Normal and Normal Request Modes, the 33911 signals
through interrupts special conditions which may require a
MCU software action. Interrupts are not generated until all
pending wake-up sources are read in the Interrupt Source
Register (ISR).
While in Stop Mode, interrupts are used to signal wake-up
events. Sleep Mode does not use interrupts, wake-up is
performed by powering-up the MCU. In Normal and Normal
Request mode the wake-up source can be read by the SPI.
The interrupts are signaled to the MCU by a low logic level
of the IRQ pin, which will remain low until the interrupt is
acknowledged by a SPI read. The IRQ pin will then be driven
high.
Interrupts are only asserted while in Normal, Normal
Request and Stop mode. Interrupts are not generated while
the RST pin is low.
Following is a list of the interrupt sources in Normal and
Normal Request Modes, some of those can be masked by
writing to the SPI-Interrupt Mask Register (IMR).
The high-voltage interrupt signals when the supply line
(VS1) voltage increases above the VSOV threshold (VSOV).
Low-voltage Interrupt
The low-voltage interrupt signals when the supply line
(VS1) voltage drops below the VSUV threshold (VSUV).
Over-temperature Prewarning
Over-temperature prewarning signals when the 33911
temperature has reached the pre-shutdown warning
threshold. It is used to warn the MCU that an overtemperature shutdown in the main 5V regulator is imminent.
LIN Over-current Shutdown / Over-temperature
Shutdown / TXD Stuck At Dominant / RXD Short-Circuit
These signal fault conditions within the LIN interface will
cause the LIN driver to be disabled, except for the LIN overcurrent. In order to restart an operation, the fault must be
removed and must be acknowledged by reading the SPI.
The LINOC bit functionality in the LIN Status Register
(LINSR) is to indicate that an LIN over-current occurred and
the driver stays enabled.
High Side Over-temperature Shutdown
The high side over-temperature shutdown signals a
shutdown in the high side output.
Low Side Over-temperature Shutdown
The low side over-temperature shutdown signals a
shutdown in the low side outputs.
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
25
FUNCTIONAL DEVICE OPERATIONS
OPERATIONAL MODES
RESET
To reset an MCU, the 33911 drives the RST pin low for the
time the reset condition lasts.
After the reset source has been removed, the state
machine will drive the RST output low for at least 1ms (typical
value) before driving it high.
In the 33911 four main reset sources exist:
5V Regulator Low-voltage-Reset (VRSTTH)
The 5V regulator output VDD is continuously monitored
against brown outs. If the supply monitor detects that the
voltage at the VDD pin has dropped below the reset threshold
VRSTTH the 33911 will issue a reset. In case of an overtemperature, the voltage regulator will be disabled and the
voltage monitoring will issue a VDDOT Flag independently of
the VDD voltage.
In order to select and activate direct wake-up from Lx
inputs, the Wake-up Control Register (WUCR) must be
configured with appropriate LxWE inputs enabled or
disabled. The wake-up inputs state are read through the
Wake-up Status Register (WUSR).
Lx inputs are also used to perform cyclic sense wake-up.
Note: Selecting an Lx input in the analog multiplexer
before entering low-power mode will disable the wake-up
capability of the Lx input.
Wake-up from Wake-up inputs (L1-L2) with cyclic sense
timer enabled
During Sleep Mode, the 5V regulator is not active. Hence,
all wake-up requests from Sleep Mode require a power-up/
reset sequence.
The SBCLIN can wake-up at the end of a cyclic sense
period if on one of the two wake-up input lines (L1-L2), a state
change occurs. The HS1 switch is activated in Sleep or Stop
Modes from an internal timer. Cyclic sense and force wakeup are exclusive. If cyclic sense is enabled, the force wakeup can not be enabled.
In order to select and activate the cyclic sense wake-up
from Lx inputs, before entering in low-power modes (Stop or
Sleep Modes), the following SPI set-up has to be performed:
• In WUCR: select the Lx input to WU-enable.
• In HSCR: enable HS1.
• In TIMCR: select the CS/WD bit and determine the
cyclic sense period with CYSTx bits.
• Perform Goto Sleep/Stop command.
External Reset
Forced Wake-up
The 33911 has a bidirectional reset pin which drives the
device to a safe state (same as Reset Mode) for as long as
this pin is held low. The RST pin must be held low long
enough to pass the internal glitch filter and get recognized by
the internal reset circuit. This functionality is also active in
Stop Mode.
After the RST pin is released, there is no extra t RST to be
considered.
The 33911 can wake-up automatically after a
predetermined time spent in Sleep or Stop Mode. Cyclic
sense and forced wake-up are exclusive. If forced wake-up is
enabled, the cyclic sense can not be enabled.
To determine the wake-up period, the following SPI set-up
has to be sent before entering in low-power modes:
• In TIMCR: select the CS/WD bit and determine the lowpower mode period with CYSTx bits.
• In HSCR: the HS1 bit must be disabled.
Window Watchdog Overflow
If the watchdog counter is not properly serviced while its
window is open, the 33911 will detect an MCU software runaway and will reset the microcontroller.
Wake-Up From Sleep Mode
WAKE-UP CAPABILITIES
Once entered into one of the low-power modes (Sleep or
Stop) only wake-up sources can bring the device into Normal
Mode operation.
In Stop Mode, a wake-up is signaled to the MCU as an
interrupt, while in Sleep Mode, the wake-up is performed by
activating the 5V regulator and resetting the MCU. In both
cases, the MCU can detect the wake-up source by accessing
the SPI registers. There is no specific SPI register bit to signal
a CS wake-up or external reset. If necessary, this condition is
detected by excluding all other possible wake-up sources.
CS Wake-up
While in Stop Mode, a rising edge on the CS will cause a
wake-up. The CS wake-up does not generate an interrupt
and is not reported on the SPI.
LIN Wake-up
While in the low-power mode the 33911 monitors the
activity on the LIN bus. A dominant pulse larger than t PROPWL
followed by a dominant to recessive transition will cause a
LIN wake-up. This behavior protects the system from a shortto ground bus condition.
Wake-up from Wake-up inputs (L1-L2) with cyclic sense
disabled
The wake-up lines are dedicated to sense state changes
of external switches, and wake-up the MCU (in Sleep or Stop
Mode).
33911
26
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATIONS
OPERATIONAL MODES
RST Wake-up
While in Stop Mode, the 33911 can wake-up when the
RST pin is held low long enough to pass the internal glitch
filter. Then, it will change to Normal Request or Normal
Modes depending on the WDCONF pin configuration. The
RST wake-up does not generate an interrupt and is not
reported via the SPI.
From Stop Mode, the following wake-up events can be
configured:
• Wake-up from Lx inputs without cyclic sense
• Cyclic sense wake-up inputs
• Force wake-up
• CS wake-up
• LIN wake-up
• RST wake-up
From Sleep Mode, the following wake-up events can be
configured:
• Wake-up from Lx inputs without cyclic sense
• Cyclic sense wake-up inputs
• Force wake-up
• LIN wake-up
WINDOW WATCHDOG
The 33911 includes a configurable window watchdog
which is active in Normal Mode. The watchdog can be
configured by an external resistor connected to the WDCONF
pin. The resistor is used to achieve higher precision in the
timebase used for the watchdog.
SPI clears are performed by writing through the SPI in the
MOD bits of the Mode Control Register (MCR).
During the first half of the SPI timeout, watchdog clears are
not allowed, but after the first half of the SPI timeout window,
the clear operation opens. If a clear operation is performed
outside the window, the 33911 will reset the MCU, in the
same way as when the watchdog overflows.
WINDOW CLOSED
NO WATCHDOG CLEAR
ALLOWED
WD TIMING X 50%
To disable the watchdog function in Normal Mode, the
user must connect the WDCONF pin to ground. This
measure effectively disables Normal Request Mode. The
WDOFF bit in the Watchdog Status Register (WDSR) will be
set. This condition is only detected during Reset Mode.
If neither a resistor nor a connection to ground is detected,
the watchdog falls back to the internal lower precision
timebase of 150ms (typ.) and signals the faulty condition
through the WDSR.
The watchdog timebase can be further divided by a
prescaler which can be configured by the Timing Control
Register (TIMCR). During Normal Request Mode, the
window watchdog is not active but there is a 150ms (typ.)
timeout for leaving the Normal Request Mode. In case of a
timeout, the 33911 will enter into Reset Mode, resetting the
microcontroller before entering again into Normal Request
Mode.
HIGH SIDE OUTPUT PIN HS1
This output is one high side driver intended to drive small
resistive loads or LEDs incorporating the following features:
• PWM capability (software maskable)
• Open-load detection
• Current limitation
• Over-temperature shutdown (with maskable interrupt)
• High-voltage shutdown (software maskable)
• Cyclic sense
The high side switch is controlled by the HS1 bit in the High
Side Control Register (HSCR).
PWM Capability (direct access)
The high side driver offers additional (to the SPI control)
direct control via the PWMIN pin.
If the HS1 bit and PWMHS1 is set in the HSCR, then the
HS1 driver is turned on if the PWMIN pin is high, and turned
off if the PWMIN pin is low.
WINDOW OPEN
FOR WATCHDOG
CLEAR
WD TIMING X 50%
WD PERIOD (tPWD)
WD TIMING SELECTED BY REGISTER
ON WDCONF PIN
Figure 16. Window Watchdog Operation
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
27
FUNCTIONAL DEVICE OPERATIONS
OPERATIONAL MODES
Interrupt
Control
Module
VDD
VDD
PWMIN
High-Side Interrupt
High Voltage Shutdown
HVSE
PWMHS1
VS2
MOD1:2
on/off
HS1
Control
HS1OP
Status
HS1CL
High Side - Driver
charge pump
open load detection
current limitation
overtemperture shutdown (interrupt maskable)
high voltage shutdown (maskable)
Cyclic Sense
HS1
Wakeup
Module
Figure 17. High Side Driver HS1
Open Load Detection
The high side driver signals an open-load condition if the
current through the high side is below the open-load current
threshold.
The open-load condition is indicated with the HS1OP bits
in the High Side Status Register (HSSR).
Current Limitation
The high side driver has an output current limitation. In
combination with the over-temperature shutdown, the high
side driver is protected against over-current and short-circuit
failures.
When the driver operates in the current limitation area, it is
indicated with the bit HS1CL in the HSSR.
Note: If the driver is operating in current limitation mode
excessive power might be dissipated.
Module. The shutdown is indicated as an HS Interrupt in the
Interrupt Source Register (ISR).
A thermal shutdown of the high side driver is indicated by
setting the HS1OP and HS1CL bits simultaneously.
If the bit HSM is set in the Interrupt Mask Register (IMR)
than an interrupt (IRQ) is generated.
A write to the High Side Control Register (HSCR), when
the over-temperature condition is gone, will re-enable the
high side driver.
High-voltage Shutdown
In case of a high-voltage condition, and if the high-voltage
shutdown is enabled (bit HVSE in the Mode Control Register
(MCR) is set), the high side driver is shut down.
A write to the HSCR, when the high-voltage condition is
gone, will re-enable the high side driver.
Over-temperature Protection (HS Interrupt)
Sleep And Stop Mode
The high side driver is protected against over-temperature.
In case of an over-temperature condition, the high side driver
is shut down and the event is latched in the Interrupt Control
The high side driver can be enabled to operate in Sleep
and Stop Mode for cyclic sensing. Also see Table 5,
Operating Modes Overview.
33911
28
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATIONS
OPERATIONAL MODES
LOW SIDE OUTPUT PINS LS1 AND LS2
These outputs are two low side drivers intended to drive
relays incorporating the following features:
• PWM capability (software maskable)
• Open load detection
• Current limitation
• Over-temperature shutdown (with maskable interrupt)
• Active clamp (for driving relays)
• High-voltage shutdown (software maskable)
The low side switches are controlled by the bit LS1:2 in the
Low Side Control Register (LSCR).
HVSE
To protect the device against over-voltage when an
inductive load (relay) is turned off, an active clamp will reenable the low side FET if the voltage on the LS1 or LS2 pin
exceeds a certain level.
PWM Capability (direct access)
Each low side driver offers additional (to the SPI control)
direct control via the PWMIN pin.
If both the LS1 and PWMLS1 bits are set in the LSCR, then
the LS1 driver is turned on if the PWMIN pin is high, and
turned off if the PWMIN pin is low. The same applies to the
LS2 and PWMLS2 bits for the LS2 driver.
VDD
Interrupt
Control
Module
VDD
Low Side Interrupt
High-voltage Shutdown
PWMIN
PWMLSx
active
clamp
LSx
MOD1:2
on/off
LSx
Control
LSxOP
LSxCL
Status
Low Side - Driver
(active clamp)
Open-load Detection
Current Limitation
Over-temperture Shutdown (interrupt maskable)
High-voltage Shutdown (maskable)
PGND
Figure 18. Low Side Drivers LS1 and LS2
Open Load Detection
Each low side driver signals an open-load condition if the
current through the low side is below the open-load current
threshold.
The open-load condition is indicated with the bit LS1OP
and LS2OP in the Low Side Status Register (LSSR).
Current Limitation
Each low side driver has a current limitation. In
combination with the over-temperature shutdown, the low
side drivers are protected against over-current and shortcircuit failures.
When the drivers operate in current limitation, this is
indicated with the LS1CL and LS2CL bits in the LSSR.
Note: If the drivers are operating in current limitation mode
excessive power might be dissipated.
Over-temperature Protection (LS Interrupt)
Both low side drivers are protected against overtemperature. In case of an over-temperature condition both
low side drivers are shut down and the event is latched in the
Interrupt Control Module. The shutdown is indicated as an LS
Interrupt in the Interrupt Source Register (ISR).
If the bit LSM is set in the Interrupt Mask Register (IMR),
then an Interrupt (IRQ) is generated.
A write to the Low Side Control Register (LSCR), when the
over-temperature condition is gone, will re-enable the low
side drivers.
High-voltage Shutdown
In case of a high voltage condition, and if the high-voltage
shutdown is enabed (bit HVSE in the Mode Control Register
(MCR) is set), both low side drivers are shut down.
A write to the LSCR, when the high-voltage condition is
gone, will re-enable the low side drivers.
Sleep And Stop Mode
The low side drivers are disabled in Sleep and Stop Mode.
Also see Table 5, Operating Modes Overview.
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
29
FUNCTIONAL DEVICE OPERATIONS
OPERATIONAL MODES
LIN PHYSICAL LAYER
The LIN bus pin provides a physical layer for single-wire
communication in automotive applications. The LIN physical
layer is designed to meet the LIN physical layer specification
and has the following features:
• LIN physical layer 2.0 compliant
• Slew rate selection
• Over-current shutdown
• Over-temperature shutdown
• LIN pull-up disable in Stop and Sleep Modes
• Advanced diagnostics
• LIN dominant voltage level selection
The LIN driver is a low side MOSFET with over-current
and thermal shutdown. An internal pull-up resistor with a
serial diode structure is integrated, so no external pull-up
components are required for the application in a slave node.
The fall time from dominant to recessive and the rise time
from recessive to dominant is controlled. The symmetry
between both slopes is guaranteed.
LIN Pin
The LIN pin offers a high susceptibility immunity level from
external disturbance, guaranteeing communication.
INTERRUPT
CONTROL
MODULE
High-voltage
Shutdown
High Side
Interrupt
WAKE-UP
MODULE
LIN
Wake-up
MOD1:2
LSR0:1
VS1
LINPE
LIN – DRIVER
LDVS
RXONLY
RXSHORT
Slope and Slew Rate Control
Over-current Shutdown (interrupt maskable)
Over-temperature Shutdown (interrupt maskable)
TXDOM
LINOT
LINOC
30K
LIN
TXD
SLOPE
CONTROL
WAKE-UP
FILTER
LGND
RXD
RECEIVER
Figure 19. LIN Interface
Slew Rate Selection
The slew rate can be selected for optimized operation at
10.4 and 20kBit/s as well as a fast baud rate for test and
programming. The slew rate can be adapted with the LSR1:0
bits in the LIN Control Register (LINCR). The initial slew rate
is optimized for 20kBit/s.
LIN pin can be disconnected by clearing the LINPE bit in the
Mode Control Register (MCR). The bit LINPE also changes
the Bus wake-up threshold (VBUSWU).
This feature will reduce the current consumption in STOP
and SLEEP Modes. It also improves performance and safe
operation.
LIN Pull-up Disable In Stop And Sleep Modes
Current Limit (LIN Interrupt)
In case of a LIN bus short to GND or LIN bus leakage
during low-power mode, the internal pull-up resistor on the
The output low side FET is protected against over-current
conditions. If an over-current condition occurs (e.g. LIN bus
33911
30
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATIONS
OPERATIONAL MODES
short to VBAT), the transmitter will not be shut down. The bit
LINOC in the LIN Status Register (LINSR) is set.
If the LINM bit is set in the Interrupt Mask Register (IMR)
an Interrupt IRQ will be generated.
Over-temperature Shutdown (LIN Interrupt)
The output low side FET is protected against overtemperature conditions. If an over-temperature condition
occurs, the transmitter will be shut down and the LINOT bit in
the LINSR is set.
If the LINM bit is set in the IMR an Interrupt IRQ will be
generated.
The transmitter is automatically re-enabled once the
condition is gone and TXD is high.
A read of the LINSR with the TXD pin high will re-enable
the transmitter.
RXD Short-circuit Detection (LIN Interrupt)
The LIN transceiver has a short-circuit detection for the
RXD output pin. In case of a short-circuit condition, either 5V
or Ground, the RXSHORT bit in the LINSR is set and the
transmitter is shutdown.
If the LINM bit is set in the IMR an Interrupt IRQ will be
generated.
The transmitter is automatically re-enabled once the
condition is gone (transition on RXD) and TXD is high.
A read of the LINSR without the RXD pin short-circuit
condition will clear the RXSHORT bit.
TXD Dominant Detection (LIN Interrupt)
The LIN transceiver monitors the TXD input pin to detect
stuck-in-dominant (0V) condition. If a stuck condition occurs
(TXD pin 0V for more than 1 second (typ.), the transmitter is
shut down and the TXDOM bit in the LINSR is set.
If the bit LINM is set in the IMR an Interrupt IRQ will be
generated.
The transmitter is automatically re-enabled once TXD is
high.
A read of the LINSR with the TXD pin is high will clear the
bit TXDOM.
LIN Dominant Voltage Level Selection
The LIN dominant voltage level can be selected by the
LDVS bit in the LIN Control Register (LINCR).
LIN Receiver Operation Only
While in Normal Mode, the activation of the RXONLY bit
disables the LIN TXD driver. If a LIN error condition occurs,
this bit is automatically set. Ifa low-power mode is selected
with this bit set, the LIN wake-up functionality is disabled.
Then in STOP mode, the RXD pin will reflect the state of the
LIN bus.
STOP Mode And Wake-up Feature
During Stop Mode operation, the transmitter of the
physical layer is disabled. If the LIN-PU bit was set in the Stop
Mode sequence, the internal pull-up resistor is disconnected
from VSUP and a small current source keeps the LIN pin in
the recessive state. The receiver is still active and able to
detect wake-up events on the LIN bus line.
A dominant level longer than tPROPWL followed by a rising
edge will generate a wake-up interrupt and will be reported in
the Interrupt Source Register (ISR). Also see Figure 11,
page 18.
SLEEP Mode And Wake-Up Feature
During Sleep Mode operation, the transmitter of the
physical layer is disabled. If the LIN-PU bit was set in the
Sleep Mode sequence, the internal pull-up resistor is
disconnected from VSUP and a small current source keeps
the LIN pin in recessive state. The receiver must still active to
detect wake-up events on the LIN bus line.
A dominant level longer than tPROPWL followed by a rising
edge will generate a system wake-up (Reset), and will be
reported in the ISR. Also see Figure 10, page 18.
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
31
FUNCTIONAL DEVICE OPERATIONS
LOGIC COMMANDS AND REGISTERS
LOGIC COMMANDS AND REGISTERS
33911 SPI INTERFACE AND CONFIGURATION
• MISO — Master-In Slave-Out
• SCLK— Serial Clock
A complete data transfer via the SPI consists of 1 byte.
The master sends 4 bits of address (A3:A0) + 4 bits of control
information (C3:C0) and the slave replies with 4 system
status bits (VMS,LINS,HSS,LSS) + 4 bits of status
information (S3:S0).
The serial peripheral interface creates the communication
link between a microcontroller (master) and the 33911.
The interface consists of four pins (see Figure 20):
• CS — Chip Select
• MOSI — Master-Out Slave-In
CS
Register Write Data
MOSI
A3
A2
A1
A0
C3
C2
C1
C0
S1
S0
Register Read Data
MISO
VMS LINS HSS
LSS
S3
S2
SCLK
Read Data Latch
Rising Edge of SCLK
Change MISO/MISO Output
Write Data Latch
Falling Edge of SCLK
Sample MISO/MISO Input
Figure 20. SPI Protocol
During the inactive phase of the CS (HIGH), the new data
The rising edge of the Chip Select (CS) indicates the end
transfer is prepared.
of the transfer and latches the write data (MOSI) into the
register. The CS high forces MISO to the high impedance
The falling edge of the CS indicates the start of a new data
state.
transfer and puts the MISO in the low-impedance state and
Register reset values are described along with the reset
latches the analog status data (Register read data).
condition.
Reset condition is the condition causing the bit to
With the rising edge of the SPI clock (SCLK), the data is
be set to its reset value. The main reset conditions are:
moved to MISO/MOSI pins. With the falling edge of the SPI
- Power-On Reset (POR): level at which the logic is reset
clock (SCLK), the data is sampled by the receiver.
and BATFAIL flag sets.
The data transfer is only valid if exactly 8 sample clock
- Reset Mode
edges are present during the active (low) phase of CS.
- Reset done by the RST pin (ext_reset)
33911
32
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATIONS
LOGIC COMMANDS AND REGISTERS
SPI REGISTER OVERVIEW
Table 6. System Status Register
BIT
Adress(A3:A0)
$0 - $F
Register Name / Read / Write Information
SYSSR - System Status Register
R
7
6
5
4
VMS
LINS
HSS
LSS
Table 7 summarizes the SPI Register content for Control Information (C3:C0)=W and status information (S3:S0) = R.
Table 7. SPI Register Overview
BIT
Adress(A3:A0)
Register Name / Read / Write Information
3
2
1
0
MCR - Mode Control Register
W
HVSE
LINPE
MOD2
MOD1
VSR - Voltage Status Register
R
VSOV
VSUV
VDDOT
BATFAIL
VSR - Voltage Status Register
R
VSOV
VSUV
VDDOT
BATFAIL
WUCR - Wake-up Control Register
W
-
-
L2WE
L1WE
WUSR - Wake-up Status Register
R
-
-
L2
L1
WUSR - Wake-up Status Register
R
-
-
L2
L1
LINCR - LIN Control Register
W
LDVS
RXONLY
LSR1
LSR0
LINSR - LIN Status Register
R
RXSHORT
TXDOM
LINOT
LINOC
LINSR - LIN Status Register
R
RXSHORT
TXDOM
LINOT
LINOC
HSCR - High Side Control Register
W
-
PWMHS1
-
HS1
HSSR - High Side Status Register
R
-
-
HS1OP
HS1CL
HSSR - High Side Status Register
R
-
-
HS1OP
HS1CL
LSCR - Low Side Control Register
W
PWMLS2
PWMLS1
LS2
LS1
LSSR - Low Side Status Register
R
LS2OP
LS2CL
LS1OP
LS1CL
LSSR - Low Side Status Register
R
LS2OP
LS2CL
LS1OP
LS1CL
WD2
WD1
WD0
TIMCR - Timing Control Register
W
CS/WD
CYST2
CYST1
CYST0
$0
$1
$2
$3
$4
$5
$6
$7
$8
$9
$A
WDSR - Watchdog Status Register
R
WDTO
WDERR
WDOFF
WDWO
$B
WDSR - Watchdog Status Register
R
WDTO
WDERR
WDOFF
WDWO
$C
AMUXCR - Analog Multiplexer Control Register
W
LXDS
MX2
MX1
MX0
$D
CFR - Configuration Register
W
-
CYSX8
-
-
IMR - Interrupt Mask Register
W
HSM
LSM
LINM
VMM
ISR - Interrupt Source Register
R
ISR3
ISR2
ISR1
ISR0
ISR - Interrupt Source Register
R
ISR3
ISR2
ISR1
ISR0
$E
$F
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
33
FUNCTIONAL DEVICE OPERATIONS
LOGIC COMMANDS AND REGISTERS
REGISTER DEFINITIONS
System Status Register - SYSSR
HS1CL
The System Status Register (SYSSR) is always
transferred with every SPI transmission and gives a quick
system status overview. It summarizes the status of the
Voltage Status Register (VSR), LIN Status Register (LINSR),
High Side Status Register (HSSR), and the Low Side Status
Register (LSSR).
HSS
HS1OP
Figure 23. High Side Status
LSS - Low Side Switch Status
Table 8. System Status Register
Read
S7
S6
S5
S4
VMS
LINS
HSS
LSS
This read-only bit indicates that one or more bits in the
LSSR are set.
1 = Low Side Status bit set
0 = None
VMS - Voltage Monitor Status
LS1CL
This read-only bit indicates that one or more bits in the
VSR are set.
1 = Voltage Monitor bit set
0 = None
LS1OP
LSS
LS2CL
LS2OP
Figure 24. Low Side Status
BATFAIL
VDDOT
VSUV
Mode Control Register - MCR
VMS
VSOV
Figure 21. Voltage Monitor Status
The Mode Control Register (MCR) allows to switch
between the operation modes and to configure the 33911.
Writing the MCR will return the VSR.
Table 9. Mode Control Register - $0
C3
C2
C1
C0
Write
HVSE
LINPE
MOD2
MOD1
Reset
Value
1
1
-
-
Reset
Condition
POR
POR
-
-
LINS - LIN Status
This read-only bit indicates that one or more bits in the
LINSR are set.
1 = LIN Status bit set
0 = None
LINOC
LINOT
TXDOM
HVSE - High-Voltage Shutdown Enable
LINS
RXSHORT
Figure 22. LIN Status
This write-only bit enables/disables automatic shutdown of
the high side and the low side drivers during a high-voltage
VSOV condition.
1 = automatic shutdown enabled
0 = automatic shutdown disabled
HSS - High Side Switch Status
LINPE - LIN pull-up enable.
This read-only bit indicates that one or more bits in the
HSSR are set.
1 = High Side Status bit set
0 = None
This write-only bit enables/disables the 30kΩ LIN pull-up
resistor in STOP and SLEEP modes. This bit also controls
the LIN bus wake-up threshold.
1 = LIN pull-up resistor enabled
0 = LIN pull-up resistor disabled
33911
34
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATIONS
LOGIC COMMANDS AND REGISTERS
MOD2, MOD1 - Mode Control Bits
These write-only bits select the operating mode and allow
to clear the watchdog in accordance with Table 12 Mode
Control Bits.
1 = POR Reset has occurred
0 = POR Reset has not occurred
Wake-up Control Register - WUCR
This register is used to control the digital wake-up inputs.
Writing the Wake-up Control Register (WUCR) will return the
Wake-up Status Register (WUSR).
Table 10. Mode Control Bits
MOD2
MOD1
Description
0
0
Normal Mode
0
1
Stop Mode
1
0
Sleep Mode
1
1
Normal Mode + watchdog Clear
Table 12. Wake-up Control Register - $2
Voltage Status Register - VSR
Returns the status of the several voltage monitors. This
register is also returned when writing to the Mode Control
Register (MCR).
C3
C2
C1
C0
Write
0
0
L2WE
L1WE
Reset
Value
1
1
1
1
Reset
Condition
POR, Reset Mode or ext_reset
Table 11. Voltage Status Register - $0/$1
Read
S3
S2
S1
S0
VSOV
VSUV
VDDOT
BATFAIL
VSOV - VSUP Over-voltage
This read-only bit indicates an over-voltage condition on
the VS1 pin.
1 = Over-voltage condition.
0 = Normal condition.
VSUV - VSUP Under-voltage
This read-only bit indicates an under-voltage condition on
the VS1 pin.
1 = Under-voltage condition.
0 = Normal condition.
LxWE - Wake-up Input x Enable
This write-only bit enables/disables which Lx inputs are
enabled. In Stop and Sleep mode the LxWE bit determines
which wake inputs are active for wake-up. If one of the Lx
inputs is selected on the analog multiplexer, the
corresponding LxWE is masked to 0.
1 = Wake-up Input x enabled.
0 = Wake-up Input x disabled.
Wake-up Status Register - WUSR
This register is used to monitor the digital wake-up inputs
and is also returned when writing to the WUCR.
Table 13. Wake-Up Status Register - $2/$3
Read
VDDOT - Main Voltage Regulator Over-temperature
Warning
This read-only bit indicates that the main voltage regulator
temperature reached the Over-temperature Prewarning
Threshold.
1 = Over-temperature Prewarning
0 = Normal
BATFAIL - Battery Fail Flag.
This read-only bit is set during power-up and indicates that
the 33911 had a Power On Reset (POR).
Any access to the MCR or Voltage Status Register (VSR)
will clear the BATFAIL flag.
S3
S2
S1
S0
-
-
L2
L1
Lx - Wake-up input x
This read-only bit indicates the status of the corresponding
Lx input. If the Lx input is not enabled then the according
Wake-Up status will return 0.
After a wake-up form Stop or Sleep Mode these bits also
allow to determine which input has caused the wake-up, by
first reading the Interrupt Status Register (ISR) and then
reading the WUSR.
1 = Lx Wake-up.
0 = Lx Wake-up disabled or selected as analog input.
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
35
FUNCTIONAL DEVICE OPERATIONS
LOGIC COMMANDS AND REGISTERS
LIN Control Register - LINCR
LIN Status Register - LINSR
This register controls the LIN physical interface block.
Writing the LIN Control Register (LINCR) returns the LIN
Status Register (LINSR).
Table 14. LIN Control Register - $4
This register returns the status of the LIN physical
interface block and is also returned when writing to the LIN
Control Register (LINCR).
Table 16. LIN Status Register - $4/$5
C3
C2
C1
C0
Write
LDVS
RXONLY
LSR1
LSR0
Reset
Value
0
0
0
0
Reset
Condition
POR, Reset
Mode or
ext_reset
POR, Reset
Mode, ext_reset
or LIN failure
gone*
Read
S3
S2
S1
S0
RXSHORT
TXDOM
LINOT
LINOC
RXSHORT - RXD Short-circuit
POR
* LIN failure gone: if LIN failure (overtemp, TxD/RxD short) was set, the flag
resets automatically when the failure is gone.
LDVS - LIN Dominant Voltage Select
This write-only bit controls the LIN Dominant voltage:
1 = LIN Dominant Voltage = VLIN_DOM_1 (1.7V typ)
0 = LIN Dominant Voltage = VLIN_DOM_0 (1.1V typ)
RXONLY - LIN Receiver Operation Only.
This write-only bit controls the behavior of the LIN
transmitter.
In Normal mode the activation of the RXONLY bit disables
the LIN transmitter. In case of a LIN error condition this bit is
automatically set.
In Stop Mode this bit disables the LIN wake-up
functionality and the RXD pin will reflect the state of the LIN
bus.
1 = only LIN receiver active (Normal Mode) or LIN wakeup disabled (Stop Mode).
0 = LIN fully enabled.
LSRx - LIN Slew-Rate
This write-only bit controls the LIN driver slew-rate in
accordance with Table 15.
Table 15. LIN Slew-Rate Control
LSR1
LSR0
Description
0
0
Normal Slew-Rate (up to 20kb/s)
0
1
Slow Slew-Rate (up to 10kb/s)
1
0
Fast Slew-Rate (up to 100kb/s)
1
1
Reserved
This read-only bit indicates a short-circuit condition on
RXD (shorted either to 5.0V or to Ground). The short-circuit
delay must be 8µs worst case to be detected and to shutdown
the driver. To clear this bit, it must be read after the condition
is gone (transition detected on RXD). The LIN driver is
automatically re-enabled once the condition is gone.
1 = RxD short-circuit condition.
0 = None.
TXDOM - TXD Permanent Dominant
This read-only bit signals the detection of a TXD pin stuck
at dominant (Ground) condition and the resultant shutdown in
the LIN transmitter. This condition is detected after the TXD
pin remains in dominant state for more than 1 second typical
value.
To clear this bit, it must be read after TXD has gone high.
The LIN driver is automatically re-enabled once TXD goes
high.
1 = TXD stuck at dominant fault detected.
0 = None.
LINOT - LIN Driver Over-temperature Shutdown
This read-only bit signals that the LIN transceiver was
shut-down due to over-temperature. The transmitter is
automatically re-enabled after the over-temperature
condition is gone and TXD is high. The LINOT bit is cleared
after SPI read once the condition is gone.
1 = LIN over-temperature shutdown
0 = None
LINOC - LIN Driver Over-current Shutdown
This read-only bit signals an over-current condition
occurred on the LIN pin. The LIN driver is not shut down but
an IRQ is generated. To clear this bit, it must be read after the
condition is gone.
1 = LIN over-current shutdown
0 = None
33911
36
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATIONS
LOGIC COMMANDS AND REGISTERS
High Side Control Register - HSCR
Low Side Control Register - LSCR
This register controls the operation of the high side driver.
Writing to this register returns the High Side Status Register
(HSSR).
Table 17. High Side Control Register - $6
This register controls the operation of the low side drivers.
Writing the Low Side Control Register (LSCR) will also return
the Low Side Status Register (LSSR).
Table 19. Low Side Control Register - $8
C3
C2
C1
C0
Write
0
PWMHS1
0
HS1
Reset
Value
0
0
0
0
Reset
Condition
POR, Reset Mode, ext_reset, HS1
overtemp or (VSOV & HVSE)
POR
C3
C2
C1
C0
Write
PWMLS2
PWMLS1
LS2
LS1
Reset
Value
0
0
0
0
Reset
Condition
POR, Reset Mode, ext_reset, LSx
overtemp or (VSOV & HVSE)
POR
PWMHS1 - PWM Input Control Enable.
PWMLx - PWM input control enable.
This write-only bit enables/disables the PWMIN input pin
to control the high side switch. The high side switch must be
enabled (HS1 bit).
1 = PWMIN input controls HS1 output.
0 = HS1 is controlled only by SPI.
This write-only bit enables/disables the PWMIN input pin
to control the respective low side switch. The corresponding
low side switch must be enabled (LSx bit).
1 = PWMIN input controls LSx.
0 = LSx is controlled only by SPI.
HS1 - High Side Switch Control.
LSx - LSx switch control.
This write-only bit enables/disables the high side switch.
1 = HS1 switch on.
0 = HS1 switch off.
This write-only bit enables/disables the corresponding low
side switch.
1 = LSx switch on.
0 = LSx switch off.
High Side Status Register - HSSR
This register returns the status of the high side switch and
is also returned when writing to the High Side Control
Register (HSCR).
Table 18. High Side Status Register - $6/$7
Read
S3
S2
S1
S0
-
-
HS1OP
HS1CL
Low Side Status Register - LSSR
This register returns the status of the low side switches
and is also returned when writing to the LSCR.
Table 20. Low Side Status Register - $8/$9
Read
C3
C2
C1
C0
LS2OP
LS2CL
LS1OP
LS1CL
High Side thermal shutdown
A thermal shutdown of the high side drivers is indicated by
setting the HS1OP and HS1CL bits simultaneously.
Low Side thermal shutdown
A thermal shutdown of the low side drivers is indicated by
setting all LSxOP and LSxCL bits simultaneously.
HS1OP - High Side Switch Open-Load Detection
This read-only bit signals that the high side switch is
conducting current below a certain threshold indicating
possible load disconnection.
1 = HS1 Open Load detected (or thermal shutdown)
0 = Normal
LSxOP - Low Side Switch Open-Load Detection
This read-only bit signals that the low side switches are
conducting current below a certain threshold indicating
possible load disconnection.
1 = LSx Open-load detected (or thermal shutdown)
0 = Normal
HS1CL - High Side Current Limitation
This read-only bit indicates that the high side switch is
operating in current limitation mode.
1 = HS1 in current limitation (or thermal shutdown)
0 = Normal
LSxCL - Low Side Current Limitation
This read-only bit indicates that the respective low side
switch is operating in current limitation mode.
1 = LSx in current limitation (or thermal shutdown)
0 = Normal
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
37
FUNCTIONAL DEVICE OPERATIONS
LOGIC COMMANDS AND REGISTERS
Timing Control Register - TIMCR
This register is a double purpose register which allows to
configure the watchdog and the cyclic sense periods. Writing
to the Timing Control Register (TIMCR) will also return the
Watchdog Status Register (WDSR).
This option is only active if the high side switch is enabled
when entering in Stop or Sleep Mode. Otherwise a timed
wake-up is performed after the period shown in Table 23.
Table 23. Cyclic Sense Interval
CYSX8(59)
CYST2
CYST1
CYST0
Interval
X
0
0
0
No cyclic sense
0
0
0
1
20ms
0
0
1
0
40ms
0
0
1
1
60ms
0
1
0
0
80ms
0
1
0
1
100ms
0
1
1
0
120ms
0
1
1
1
140ms
1
0
0
1
160ms
CS/WD - Cyclic Sense or Watchdog prescaler select.
1
0
1
0
320ms
This write-only bit selects which prescaler is being written
to, the Cyclic Sense prescaler or the watchdog prescaler.
1 = Cyclic Sense Prescaler selected
0 = watchdog Prescaler select
1
0
1
1
480ms
1
1
0
0
640ms
1
1
0
1
800ms
1
1
1
0
960ms
1
1
1
1
1120ms
Table 21. Timing Control Register - $A
C3
Write
C2
C1
C0
WD2
WD1
WD0
CS/WD
CYST2
Reset
Value
Reset
Condition
-
0
-
CYST1
CYST0
0
0
POR
WDx - Watchdog Prescaler
This write-only bits selects the divider for the watchdog
prescaler and therefore selects the watchdog period in
accordance with Table 22. This configuration is valid only if
windowing watchdog is active.
Table 22. Watchdog Prescaler
WD2
WD1
WD0
Prescaler Divider
0
0
0
1
0
0
1
2
0
1
0
4
0
1
1
6
1
0
0
8
1
0
1
10
1
1
0
12
1
1
1
14
CYSTx - Cyclic Sense Period Prescaler Select
This write-only bits selects the interval for the wake-up
cyclic sensing together with the bit CYSX8 in the
Configuration Register (CFR) (see page 39).
Notes
59. bit CYSX8 is located in Configuration Register (CFR)
Watchdog Status Register - WDSR
This register returns the watchdog status information and
is also returned when writing to the TIMCR.
Table 24. Watchdog Status Register - $A/$B
Read
S3
S2
S1
S0
WDTO
WDERR
WDOFF
WDWO
WDTO - Watchdog Timeout
This read-only bit signals the last reset was caused by
either a watchdog timeout or by an attempt to clear the
watchdog within the window closed.
Any access to this register or the TIMCR will clear the
WDTO bit.
1 = Last reset caused by watchdog timeout
0 = None
33911
38
Analog Integrated Circuit Device Data
Freescale Semiconductor
FUNCTIONAL DEVICE OPERATIONS
LOGIC COMMANDS AND REGISTERS
WDERR - Watchdog Error
MXx - Analog Multiplexer Input Select
This read-only bit signals the detection of a missing
watchdog resistor. In this condition the watchdog is using the
internal, lower precision timebase. The Windowing function is
disabled.
1 = WDCONF pin resistor missing
0 = WDCONF pin resistor not floating
These write-only bits selects which analog input is
multiplexed to the ADOUT0 pin according to Table 26.
When disabled or when in Stop or Sleep Mode, the output
buffer is not powered and the ADOUT0 output is left floating
to achieve lower current consumption.
WDOFF - Watchdog Off
Table 26. Analog Multiplexer Channel Select
This read-only bit signals that the watchdog pin connected
to Ground and therefore disabled. In this case watchdog
timeouts are disabled and the device automatically enters
Normal Mode out of Reset. This might be necessary for
software debugging and for programming the Flash memory.
1 = Watchdog is disabled
0 = Watchdog is enabled
WDWO - Watchdog Window Open
This read-only bit signals when the watchdog window is
open for clears. The purpose of this bit is for testing. Should
be ignored in case WDERR is High.
1 = Watchdog window open
0 = Watchdog window closed
Analog Multiplexer Control Register - MUXCR
This register controls the analog multiplexer and selects
the divider ration for the Lx input divider.
Table 25. Analog Multiplexer Control Register -$C
C3
C2
C1
C0
Write
LXDS
MX2
MX1
MX0
Reset
Value
1
0
0
0
Reset
Condition
POR
MX2
MX1
MX0
Meaning
0
0
0
Disabled
0
0
1
Reserved
0
1
0
Die Temperature Sensor
0
1
1
VSENSE input
1
0
0
L1 input
1
0
1
L2 input
1
1
0
Reserved
1
1
1
Reserved
Configuration Register - CFR
This register controls the cyclic sense timing multiplier.
Table 27. Configuration Register - $D
C3
C2
C1
C0
Write
0
CYSX8
0
0
Reset
Value
0
0
0
0
Reset
Condition
POR, Reset
Mode or
ext_reset
POR
POR
POR
CYSX8 - Cyclic Sense Timing x 8.
POR, Reset Mode or ext_reset
LXDS - Lx Analog Input Divider Select
This write-only bit selects the resistor divider for the Lx
analog inputs. Voltage is internally clamped to VDD.
0 = Lx Analog divider: 1
1 = Lx Analog divider: 3.6 (typ.)
This write-only bit influences the cyclic sense period as
shown in Table 23.
1 = Multiplier enabled
0 = None
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
39
FUNCTIONAL DEVICE OPERATIONS
LOGIC COMMANDS AND REGISTERS
Interrupt Mask Register - IMR
LINM - LIN Interrupts Mask
This register allow to mask some of interrupt sources. The
respective flags within the Interrupt Source Register (ISR) will
continue to work but will not generate interrupts to the MCU.
The 5V Regulator over-temperature prewarning interrupt and
Under Voltage (VSUV) interrupts can not be masked and will
always cause an interrupt.
This write-only bit enables/disables interrupts generated in
the LIN block.
1 = LIN Interrupts Enabled
0 = LIN Interrupts Disabled
VMM - Voltage Monitor Interrupt Mask
Writing to the Interrupt Mask Register (IMR) will return the
ISR.
This write-only bit enables/disables interrupts generated in
the Voltage Monitor block. The only maskable interrupt in the
Voltage Monitor Block is the VSUP over-voltage interrupt.
1 = Interrupts Enabled
0 = Interrupts Disabled
Table 28. Interrupt Mask Register - $E
Write
C3
C2
C1
C0
HSM
LSM
LINM
VMM
Interrupt Source Register - ISR
Reset
Value
1
1
Reset
Condition
1
1
This register allows the MCU to determine the source of
the last interrupt or wake-up respectively. A read of the
register acknowledges the interrupt and leads IRQ pin to
high, in case there are no other pending interrupts. If there
are pending interrupts, IRQ will be driven high for 10µs and
then be driven low again.
This register is also returned when writing to the IMR.
POR
HSM - High Side Interrupt Mask
This write-only bit enables/disables interrupts generated in
the high side block.
1 = HS Interrupts Enabled
0 = HS Interrupts Disabled
Table 29. Interrupt Source Register - $E/$F
Read
LSM - Low Side Interrupt Mask
This write-only bit enables/disables interrupts generated in
the low side block.
1 = LS Interrupts Enabled
0 = LS Interrupts Disabled
S3
S2
S1
S0
ISR3
ISR2
ISR1
ISR0
ISRx - Interrupt Source Register
These read-only bits indicate the interrupt source following
Table 30. If no interrupt is pending than all bits are 0.
In case more than one interrupt is pending, than the
interrupt sources are handled sequentially multiplex.
Table 30. Interrupt Sources
Interrupt Source
ISR3 ISR2 ISR1 ISR0
none maskable
maskable
0
0
0
0
0
0
0
1
0
0
1
0
-
HS Interrupt (Over-temperature)
0
0
1
1
-
LS Interrupt (Over-temperature)
0
1
0
0
0
1
0
1
0
1
1
0
no interrupt
Priority
no interrupt
none
Lx Wake-up from Stop Mode-
highest
LIN Interrupt (RXSHORT, TXDOM, LIN OT, LIN
OC) or LIN Wake-up
Voltage Monitor Interrupt
Voltage Monitor Interrupt
(Low-voltage and VDD over-temperature)
(High-voltage)
-
Forced Wake-up
lowest
33911
40
Analog Integrated Circuit Device Data
Freescale Semiconductor
TYPICAL APPLICATION
LOGIC COMMANDS AND REGISTERS
TYPICAL APPLICATION
The 33911 can be configured in several applications. The figure below shows the 33911 in the typical Slave Node Application.
V BAT
VS2
VS1
D1
C2
C1
Interrupt
Control Module
LVI, HVI, HTI, OCI
IRQ
C4
Internal
Bus
VDD
C3
Voltage Regulator
AGND
VDD
Reset
Control Module
LVR, HVR, HTR, WD,
RST
IRQ
LS1
HB Type Relay
Low Side Control
Module
RST
TIMER
LS2
PGND
Window
Watchdog Module
PWMIN
R1
Motor Output
High Side Control
Module
HS1
MISO
MOSI
Chip Temp Sense Module
SCLK
Analog Multiplexer
SPI
&
CONTROL
SPI
CS
MCU
VSENSE
VBAT Sense Module
R2
L1
Analog Input Module
A/D
ADOUT0
L2
R3
Wake Up Module
Digital Input Module
RXD
LIN Physical Layer
SCI
LIN
LIN
TXD
WDCONF
LGND
AGND
PGND
C5
R4
Typical Component Values:
C1 = 47µF; C2 = C4 = 100nF; C3 = 10µF; C5 = 220pF
R1 = 10kΩ; R2 = R3 = 10kΩ; R4 = 20kΩ-200kΩ
Recommended Configuration of the not Connected Pins (NC):
Pin 15, 16, 20, 21 = GND
Pin 11, 30 = open (floating)
Pin 24 = open (floating) or VS2
Pin 28 = this pin is not internally connected and may be used for PCB routing
optimization.
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
41
PACKAGING
PACKAGE DIMENSIONS
PACKAGING
PACKAGE DIMENSIONS
Important For the most current revision of the package, visit www.Freescale.com and select Documentation, then under
Available Documentation column select Packaging Information.
AC SUFFIX (PB-FREE)
32-PIN LQFP
98ASH70029A
REVISION D
33911
42
Analog Integrated Circuit Device Data
Freescale Semiconductor
IMPORTANT FOR THE MOST CURRENT REVISION OF THE PACKAGE, VISIT WWW.FREESCALE.COM AND SELECT DOCUMENTATION,
AC SUFFIX (PB-FREE)
32-PIN LQFP
98ASH70029A
REVISION D
33911
Analog Integrated Circuit Device Data
Freescale Semiconductor
43
REVISION HISTORY
PACKAGE DIMENSIONS
REVISION HISTORY
Revision
Date
Description of Changes
3.0
9/2007
•
Initial Release
4.0
2/2008
•
•
Changed Functional Block Diagram on page 22.
Corrected typo for Outline drawing number (98A...).
33911
44
Analog Integrated Circuit Device Data
Freescale Semiconductor
How to Reach Us:
Home Page:
www.freescale.com
Web Support:
http://www.freescale.com/support
USA/Europe or Locations Not Listed:
Freescale Semiconductor, Inc.
Technical Information Center, EL516
2100 East Elliot Road
Tempe, Arizona 85284
+1-800-521-6274 or +1-480-768-2130
www.freescale.com/support
Europe, Middle East, and Africa:
Freescale Halbleiter Deutschland GmbH
Technical Information Center
Schatzbogen 7
81829 Muenchen, Germany
+44 1296 380 456 (English)
+46 8 52200080 (English)
+49 89 92103 559 (German)
+33 1 69 35 48 48 (French)
www.freescale.com/support
Japan:
Freescale Semiconductor Japan Ltd.
Headquarters
ARCO Tower 15F
1-8-1, Shimo-Meguro, Meguro-ku,
Tokyo 153-0064
Japan
0120 191014 or +81 3 5437 9125
[email protected]
Asia/Pacific:
Freescale Semiconductor Hong Kong Ltd.
Technical Information Center
2 Dai King Street
Tai Po Industrial Estate
Tai Po, N.T., Hong Kong
+800 2666 8080
[email protected]
For Literature Requests Only:
Freescale Semiconductor Literature Distribution Center
P.O. Box 5405
Denver, Colorado 80217
1-800-441-2447 or 303-675-2140
Fax: 303-675-2150
[email protected]
Information in this document is provided solely to enable system and software
implementers to use Freescale Semiconductor products. There are no express or
implied copyright licenses granted hereunder to design or fabricate any integrated
circuits or integrated circuits based on the information in this document.
Freescale Semiconductor reserves the right to make changes without further notice to
any products herein. Freescale Semiconductor makes no warranty, representation or
guarantee regarding the suitability of its products for any particular purpose, nor does
Freescale Semiconductor assume any liability arising out of the application or use of any
product or circuit, and specifically disclaims any and all liability, including without
limitation consequential or incidental damages. “Typical” parameters that may be
provided in Freescale Semiconductor data sheets and/or specifications can and do vary
in different applications and actual performance may vary over time. All operating
parameters, including “Typicals”, must be validated for each customer application by
customer’s technical experts. Freescale Semiconductor does not convey any license
under its patent rights nor the rights of others. Freescale Semiconductor products are
not designed, intended, or authorized for use as components in systems intended for
surgical implant into the body, or other applications intended to support or sustain life,
or for any other application in which the failure of the Freescale Semiconductor product
could create a situation where personal injury or death may occur. Should Buyer
purchase or use Freescale Semiconductor products for any such unintended or
unauthorized application, Buyer shall indemnify and hold Freescale Semiconductor and
its officers, employees, subsidiaries, affiliates, and distributors harmless against all
claims, costs, damages, and expenses, and reasonable attorney fees arising out of,
directly or indirectly, any claim of personal injury or death associated with such
unintended or unauthorized use, even if such claim alleges that Freescale
Semiconductor was negligent regarding the design or manufacture of the part.
Freescale™ and the Freescale logo are trademarks of Freescale Semiconductor, Inc.
All other product or service names are the property of their respective owners.
© Freescale Semiconductor, Inc., 2007. All rights reserved.
MC33911
Rev. 4.0
2/2008
Similar pages